wok: asterisk/stuff/rfc3951.txt annotate

wok annotate asterisk/stuff/rfc3951.txt @ rev 19975

Up sshfs-fuse (2.9)

author	Pascal Bellard <pascal.bellard@slitaz.org>
date	Sun Jun 11 12:13:33 2017 +0200 (2017-06-11)
parents
children

rev	line source
pascal@12756	1
pascal@12756	2
pascal@12756	3
pascal@12756	4
pascal@12756	5
pascal@12756	6
pascal@12756	7 Network Working Group S. Andersen
pascal@12756	8 Request for Comments: 3951 Aalborg University
pascal@12756	9 Category: Experimental A. Duric
pascal@12756	10 Telio
pascal@12756	11 H. Astrom
pascal@12756	12 R. Hagen
pascal@12756	13 W. Kleijn
pascal@12756	14 J. Linden
pascal@12756	15 Global IP Sound
pascal@12756	16 December 2004
pascal@12756	17
pascal@12756	18
pascal@12756	19 Internet Low Bit Rate Codec (iLBC)
pascal@12756	20
pascal@12756	21 Status of this Memo
pascal@12756	22
pascal@12756	23 This memo defines an Experimental Protocol for the Internet
pascal@12756	24 community. It does not specify an Internet standard of any kind.
pascal@12756	25 Discussion and suggestions for improvement are requested.
pascal@12756	26 Distribution of this memo is unlimited.
pascal@12756	27
pascal@12756	28 Copyright Notice
pascal@12756	29
pascal@12756	30 Copyright (C) The Internet Society (2004).
pascal@12756	31
pascal@12756	32 Abstract
pascal@12756	33
pascal@12756	34 This document specifies a speech codec suitable for robust voice
pascal@12756	35 communication over IP. The codec is developed by Global IP Sound
pascal@12756	36 (GIPS). It is designed for narrow band speech and results in a
pascal@12756	37 payload bit rate of 13.33 kbit/s for 30 ms frames and 15.20 kbit/s
pascal@12756	38 for 20 ms frames. The codec enables graceful speech quality
pascal@12756	39 degradation in the case of lost frames, which occurs in connection
pascal@12756	40 with lost or delayed IP packets.
pascal@12756	41
pascal@12756	42
pascal@12756	43
pascal@12756	44
pascal@12756	45
pascal@12756	46
pascal@12756	47
pascal@12756	48
pascal@12756	49
pascal@12756	50
pascal@12756	51
pascal@12756	52
pascal@12756	53
pascal@12756	54
pascal@12756	55
pascal@12756	56
pascal@12756	57
pascal@12756	58 Andersen, et al. Experimental [Page 1]
pascal@12756	59
pascal@12756	60 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	61
pascal@12756	62
pascal@12756	63 Table of Contents
pascal@12756	64
pascal@12756	65 1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4
pascal@12756	66 2. Outline of the Codec . . . . . . . . . . . . . . . . . . . . . 5
pascal@12756	67 2.1. Encoder. . . . . . . . . . . . . . . . . . . . . . . . . 5
pascal@12756	68 2.2. Decoder. . . . . . . . . . . . . . . . . . . . . . . . . 7
pascal@12756	69 3. Encoder Principles . . . . . . . . . . . . . . . . . . . . . . 7
pascal@12756	70 3.1. Pre-processing . . . . . . . . . . . . . . . . . . . . . 9
pascal@12756	71 3.2. LPC Analysis and Quantization. . . . . . . . . . . . . . 9
pascal@12756	72 3.2.1. Computation of Autocorrelation Coefficients. . . 10
pascal@12756	73 3.2.2. Computation of LPC Coefficients. . . . . . . . . 11
pascal@12756	74 3.2.3. Computation of LSF Coefficients from LPC
pascal@12756	75 Coefficients . . . . . . . . . . . . . . . . . . 11
pascal@12756	76 3.2.4. Quantization of LSF Coefficients . . . . . . . . 12
pascal@12756	77 3.2.5. Stability Check of LSF Coefficients. . . . . . . 13
pascal@12756	78 3.2.6. Interpolation of LSF Coefficients. . . . . . . . 13
pascal@12756	79 3.2.7. LPC Analysis and Quantization for 20 ms Frames . 14
pascal@12756	80 3.3. Calculation of the Residual. . . . . . . . . . . . . . . 15
pascal@12756	81 3.4. Perceptual Weighting Filter. . . . . . . . . . . . . . . 15
pascal@12756	82 3.5. Start State Encoder. . . . . . . . . . . . . . . . . . . 15
pascal@12756	83 3.5.1. Start State Estimation . . . . . . . . . . . . . 16
pascal@12756	84 3.5.2. All-Pass Filtering and Scale Quantization. . . . 17
pascal@12756	85 3.5.3. Scalar Quantization. . . . . . . . . . . . . . . 18
pascal@12756	86 3.6. Encoding the Remaining Samples . . . . . . . . . . . . . 19
pascal@12756	87 3.6.1. Codebook Memory. . . . . . . . . . . . . . . . . 20
pascal@12756	88 3.6.2. Perceptual Weighting of Codebook Memory
pascal@12756	89 and Target . . . . . . . . . . . . . . . . . . . 22
pascal@12756	90 3.6.3. Codebook Creation. . . . . . . . . . . . . . . . 23
pascal@12756	91 3.6.3.1. Creation of a Base Codebook . . . . . . 23
pascal@12756	92 3.6.3.2. Codebook Expansion. . . . . . . . . . . 24
pascal@12756	93 3.6.3.3. Codebook Augmentation . . . . . . . . . 24
pascal@12756	94 3.6.4. Codebook Search. . . . . . . . . . . . . . . . . 26
pascal@12756	95 3.6.4.1. Codebook Search at Each Stage . . . . . 26
pascal@12756	96 3.6.4.2. Gain Quantization at Each Stage . . . . 27
pascal@12756	97 3.6.4.3. Preparation of Target for Next Stage. . 28
pascal@12756	98 3.7. Gain Correction Encoding . . . . . . . . . . . . . . . . 28
pascal@12756	99 3.8. Bitstream Definition . . . . . . . . . . . . . . . . . . 29
pascal@12756	100 4. Decoder Principles . . . . . . . . . . . . . . . . . . . . . . 32
pascal@12756	101 4.1. LPC Filter Reconstruction. . . . . . . . . . . . . . . . 33
pascal@12756	102 4.2. Start State Reconstruction . . . . . . . . . . . . . . . 33
pascal@12756	103 4.3. Excitation Decoding Loop . . . . . . . . . . . . . . . . 34
pascal@12756	104 4.4. Multistage Adaptive Codebook Decoding. . . . . . . . . . 35
pascal@12756	105 4.4.1. Construction of the Decoded Excitation Signal. . 35
pascal@12756	106 4.5. Packet Loss Concealment. . . . . . . . . . . . . . . . . 35
pascal@12756	107 4.5.1. Block Received Correctly and Previous Block
pascal@12756	108 Also Received. . . . . . . . . . . . . . . . . . 35
pascal@12756	109 4.5.2. Block Not Received . . . . . . . . . . . . . . . 36
pascal@12756	110
pascal@12756	111
pascal@12756	112
pascal@12756	113
pascal@12756	114 Andersen, et al. Experimental [Page 2]
pascal@12756	115
pascal@12756	116 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	117
pascal@12756	118
pascal@12756	119 4.5.3. Block Received Correctly When Previous Block
pascal@12756	120 Not Received . . . . . . . . . . . . . . . . . . 36
pascal@12756	121 4.6. Enhancement. . . . . . . . . . . . . . . . . . . . . . . 37
pascal@12756	122 4.6.1. Estimating the Pitch . . . . . . . . . . . . . . 39
pascal@12756	123 4.6.2. Determination of the Pitch-Synchronous
pascal@12756	124 Sequences. . . . . . . . . . . . . . . . . . . . 39
pascal@12756	125 4.6.3. Calculation of the Smoothed Excitation . . . . . 41
pascal@12756	126 4.6.4. Enhancer Criterion . . . . . . . . . . . . . . . 41
pascal@12756	127 4.6.5. Enhancing the Excitation . . . . . . . . . . . . 42
pascal@12756	128 4.7. Synthesis Filtering. . . . . . . . . . . . . . . . . . . 43
pascal@12756	129 4.8. Post Filtering . . . . . . . . . . . . . . . . . . . . . 43
pascal@12756	130 5. Security Considerations. . . . . . . . . . . . . . . . . . . . 43
pascal@12756	131 6. Evaluation of the iLBC Implementations . . . . . . . . . . . . 43
pascal@12756	132 7. References . . . . . . . . . . . . . . . . . . . . . . . . . . 43
pascal@12756	133 7.1. Normative References . . . . . . . . . . . . . . . . . . 43
pascal@12756	134 7.2. Informative References . . . . . . . . . . . . . . . . . 44
pascal@12756	135 8. ACKNOWLEDGEMENTS . . . . . . . . . . . . . . . . . . . . . . . 44
pascal@12756	136 APPENDIX A: Reference Implementation . . . . . . . . . . . . . . . 45
pascal@12756	137 A.1. iLBC_test.c. . . . . . . . . . . . . . . . . . . . . . . 46
pascal@12756	138 A.2 iLBC_encode.h. . . . . . . . . . . . . . . . . . . . . . 52
pascal@12756	139 A.3. iLBC_encode.c. . . . . . . . . . . . . . . . . . . . . . 53
pascal@12756	140 A.4. iLBC_decode.h. . . . . . . . . . . . . . . . . . . . . . 63
pascal@12756	141 A.5. iLBC_decode.c. . . . . . . . . . . . . . . . . . . . . . 64
pascal@12756	142 A.6. iLBC_define.h. . . . . . . . . . . . . . . . . . . . . . 76
pascal@12756	143 A.7. constants.h. . . . . . . . . . . . . . . . . . . . . . . 80
pascal@12756	144 A.8. constants.c. . . . . . . . . . . . . . . . . . . . . . . 82
pascal@12756	145 A.9. anaFilter.h. . . . . . . . . . . . . . . . . . . . . . . 96
pascal@12756	146 A.10. anaFilter.c. . . . . . . . . . . . . . . . . . . . . . . 97
pascal@12756	147 A.11. createCB.h . . . . . . . . . . . . . . . . . . . . . . . 98
pascal@12756	148 A.12. createCB.c . . . . . . . . . . . . . . . . . . . . . . . 99
pascal@12756	149 A.13. doCPLC.h . . . . . . . . . . . . . . . . . . . . . . . .104
pascal@12756	150 A.14. doCPLC.c . . . . . . . . . . . . . . . . . . . . . . . .104
pascal@12756	151 A.15. enhancer.h . . . . . . . . . . . . . . . . . . . . . . .109
pascal@12756	152 A.16. enhancer.c . . . . . . . . . . . . . . . . . . . . . . .110
pascal@12756	153 A.17. filter.h . . . . . . . . . . . . . . . . . . . . . . . .123
pascal@12756	154 A.18. filter.c . . . . . . . . . . . . . . . . . . . . . . . .125
pascal@12756	155 A.19. FrameClassify.h. . . . . . . . . . . . . . . . . . . . .128
pascal@12756	156 A.20. FrameClassify.c. . . . . . . . . . . . . . . . . . . . .129
pascal@12756	157 A.21. gainquant.h. . . . . . . . . . . . . . . . . . . . . . .131
pascal@12756	158 A.22. gainquant.c. . . . . . . . . . . . . . . . . . . . . . .131
pascal@12756	159 A.23. getCBvec.h . . . . . . . . . . . . . . . . . . . . . . .134
pascal@12756	160 A.24. getCBvec.c . . . . . . . . . . . . . . . . . . . . . . .134
pascal@12756	161 A.25. helpfun.h. . . . . . . . . . . . . . . . . . . . . . . .138
pascal@12756	162 A.26. helpfun.c. . . . . . . . . . . . . . . . . . . . . . . .140
pascal@12756	163 A.27. hpInput.h. . . . . . . . . . . . . . . . . . . . . . . .146
pascal@12756	164 A.28. hpInput.c. . . . . . . . . . . . . . . . . . . . . . . .146
pascal@12756	165 A.29. hpOutput.h . . . . . . . . . . . . . . . . . . . . . . .148
pascal@12756	166 A.30. hpOutput.c . . . . . . . . . . . . . . . . . . . . . . .148
pascal@12756	167
pascal@12756	168
pascal@12756	169
pascal@12756	170 Andersen, et al. Experimental [Page 3]
pascal@12756	171
pascal@12756	172 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	173
pascal@12756	174
pascal@12756	175 A.31. iCBConstruct.h . . . . . . . . . . . . . . . . . . . . .149
pascal@12756	176 A.32. iCBConstruct.c . . . . . . . . . . . . . . . . . . . . .150
pascal@12756	177 A.33. iCBSearch.h. . . . . . . . . . . . . . . . . . . . . . .152
pascal@12756	178 A.34. iCBSearch.c. . . . . . . . . . . . . . . . . . . . . . .153
pascal@12756	179 A.35. LPCdecode.h. . . . . . . . . . . . . . . . . . . . . . .163
pascal@12756	180 A.36. LPCdecode.c. . . . . . . . . . . . . . . . . . . . . . .164
pascal@12756	181 A.37. LPCencode.h. . . . . . . . . . . . . . . . . . . . . . .167
pascal@12756	182 A.38. LPCencode.c. . . . . . . . . . . . . . . . . . . . . . .167
pascal@12756	183 A.39. lsf.h. . . . . . . . . . . . . . . . . . . . . . . . . .172
pascal@12756	184 A.40. lsf.c. . . . . . . . . . . . . . . . . . . . . . . . . .172
pascal@12756	185 A.41. packing.h. . . . . . . . . . . . . . . . . . . . . . . .178
pascal@12756	186 A.42. packing.c. . . . . . . . . . . . . . . . . . . . . . . .179
pascal@12756	187 A.43. StateConstructW.h. . . . . . . . . . . . . . . . . . . .182
pascal@12756	188 A.44. StateConstructW.c. . . . . . . . . . . . . . . . . . . .183
pascal@12756	189 A.45. StateSearchW.h . . . . . . . . . . . . . . . . . . . . .185
pascal@12756	190 A.46. StateSearchW.c . . . . . . . . . . . . . . . . . . . . .186
pascal@12756	191 A.47. syntFilter.h . . . . . . . . . . . . . . . . . . . . . .190
pascal@12756	192 A.48. syntFilter.c . . . . . . . . . . . . . . . . . . . . . .190
pascal@12756	193 Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . .192
pascal@12756	194 Full Copyright Statement . . . . . . . . . . . . . . . . . . . . .194
pascal@12756	195
pascal@12756	196 1. Introduction
pascal@12756	197
pascal@12756	198 This document contains the description of an algorithm for the coding
pascal@12756	199 of speech signals sampled at 8 kHz. The algorithm, called iLBC, uses
pascal@12756	200 a block-independent linear-predictive coding (LPC) algorithm and has
pascal@12756	201 support for two basic frame lengths: 20 ms at 15.2 kbit/s and 30 ms
pascal@12756	202 at 13.33 kbit/s. When the codec operates at block lengths of 20 ms,
pascal@12756	203 it produces 304 bits per block, which SHOULD be packetized as in [1].
pascal@12756	204 Similarly, for block lengths of 30 ms it produces 400 bits per block,
pascal@12756	205 which SHOULD be packetized as in [1]. The two modes for the
pascal@12756	206 different frame sizes operate in a very similar way. When they
pascal@12756	207 differ it is explicitly stated in the text, usually with the notation
pascal@12756	208 x/y, where x refers to the 20 ms mode and y refers to the 30 ms mode.
pascal@12756	209
pascal@12756	210 The described algorithm results in a speech coding system with a
pascal@12756	211 controlled response to packet losses similar to what is known from
pascal@12756	212 pulse code modulation (PCM) with packet loss concealment (PLC), such
pascal@12756	213 as the ITU-T G.711 standard [4], which operates at a fixed bit rate
pascal@12756	214 of 64 kbit/s. At the same time, the described algorithm enables
pascal@12756	215 fixed bit rate coding with a quality-versus-bit rate tradeoff close
pascal@12756	216 to state-of-the-art. A suitable RTP payload format for the iLBC
pascal@12756	217 codec is specified in [1].
pascal@12756	218
pascal@12756	219 Some of the applications for which this coder is suitable are real
pascal@12756	220 time communications such as telephony and videoconferencing,
pascal@12756	221 streaming audio, archival, and messaging.
pascal@12756	222
pascal@12756	223
pascal@12756	224
pascal@12756	225
pascal@12756	226 Andersen, et al. Experimental [Page 4]
pascal@12756	227
pascal@12756	228 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	229
pascal@12756	230
pascal@12756	231 Cable Television Laboratories (CableLabs(R)) has adopted iLBC as a
pascal@12756	232 mandatory PacketCable(TM) audio codec standard for VoIP over Cable
pascal@12756	233 applications [3].
pascal@12756	234
pascal@12756	235 This document is organized as follows. Section 2 gives a brief
pascal@12756	236 outline of the codec. The specific encoder and decoder algorithms
pascal@12756	237 are explained in sections 3 and 4, respectively. Appendix A provides
pascal@12756	238 a c-code reference implementation.
pascal@12756	239
pascal@12756	240 The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
pascal@12756	241 "SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
pascal@12756	242 document are to be interpreted as described in BCP 14, RFC 2119 [2].
pascal@12756	243
pascal@12756	244 2. Outline of the Codec
pascal@12756	245
pascal@12756	246 The codec consists of an encoder and a decoder as described in
pascal@12756	247 sections 2.1 and 2.2, respectively.
pascal@12756	248
pascal@12756	249 The essence of the codec is LPC and block-based coding of the LPC
pascal@12756	250 residual signal. For each 160/240 (20 ms/30 ms) sample block, the
pascal@12756	251 following major steps are performed: A set of LPC filters are
pascal@12756	252 computed, and the speech signal is filtered through them to produce
pascal@12756	253 the residual signal. The codec uses scalar quantization of the
pascal@12756	254 dominant part, in terms of energy, of the residual signal for the
pascal@12756	255 block. The dominant state is of length 57/58 (20 ms/30 ms) samples
pascal@12756	256 and forms a start state for dynamic codebooks constructed from the
pascal@12756	257 already coded parts of the residual signal. These dynamic codebooks
pascal@12756	258 are used to code the remaining parts of the residual signal. By this
pascal@12756	259 method, coding independence between blocks is achieved, resulting in
pascal@12756	260 elimination of propagation of perceptual degradations due to packet
pascal@12756	261 loss. The method facilitates high-quality packet loss concealment
pascal@12756	262 (PLC).
pascal@12756	263
pascal@12756	264 2.1. Encoder
pascal@12756	265
pascal@12756	266 The input to the encoder SHOULD be 16 bit uniform PCM sampled at 8
pascal@12756	267 kHz. It SHOULD be partitioned into blocks of BLOCKL=160/240 samples
pascal@12756	268 for the 20/30 ms frame size. Each block is divided into NSUB=4/6
pascal@12756	269 consecutive sub-blocks of SUBL=40 samples each. For 30 ms frame
pascal@12756	270 size, the encoder performs two LPC_FILTERORDER=10 linear-predictive
pascal@12756	271 coding (LPC) analyses. The first analysis applies a smooth window
pascal@12756	272 centered over the second sub-block and extending to the middle of the
pascal@12756	273 fifth sub-block. The second LPC analysis applies a smooth asymmetric
pascal@12756	274 window centered over the fifth sub-block and extending to the end of
pascal@12756	275 the sixth sub-block. For 20 ms frame size, one LPC_FILTERORDER=10
pascal@12756	276 linear-predictive coding (LPC) analysis is performed with a smooth
pascal@12756	277 window centered over the third sub-frame.
pascal@12756	278
pascal@12756	279
pascal@12756	280
pascal@12756	281
pascal@12756	282 Andersen, et al. Experimental [Page 5]
pascal@12756	283
pascal@12756	284 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	285
pascal@12756	286
pascal@12756	287 For each of the LPC analyses, a set of line-spectral frequencies
pascal@12756	288 (LSFs) are obtained, quantized, and interpolated to obtain LSF
pascal@12756	289 coefficients for each sub-block. Subsequently, the LPC residual is
pascal@12756	290 computed by using the quantized and interpolated LPC analysis
pascal@12756	291 filters.
pascal@12756	292
pascal@12756	293 The two consecutive sub-blocks of the residual exhibiting the maximal
pascal@12756	294 weighted energy are identified. Within these two sub-blocks, the
pascal@12756	295 start state (segment) is selected from two choices: the first 57/58
pascal@12756	296 samples or the last 57/58 samples of the two consecutive sub-blocks.
pascal@12756	297 The selected segment is the one of higher energy. The start state is
pascal@12756	298 encoded with scalar quantization.
pascal@12756	299
pascal@12756	300 A dynamic codebook encoding procedure is used to encode 1) the 23/22
pascal@12756	301 (20 ms/30 ms) remaining samples in the two sub-blocks containing the
pascal@12756	302 start state; 2) the sub-blocks after the start state in time; and 3)
pascal@12756	303 the sub-blocks before the start state in time. Thus, the encoding
pascal@12756	304 target can be either the 23/22 samples remaining of the two sub-
pascal@12756	305 blocks containing the start state or a 40-sample sub-block. This
pascal@12756	306 target can consist of samples indexed forward in time or backward in
pascal@12756	307 time, depending on the location of the start state.
pascal@12756	308
pascal@12756	309 The codebook coding is based on an adaptive codebook built from a
pascal@12756	310 codebook memory that contains decoded LPC excitation samples from the
pascal@12756	311 already encoded part of the block. These samples are indexed in the
pascal@12756	312 same time direction as the target vector, ending at the sample
pascal@12756	313 instant prior to the first sample instant represented in the target
pascal@12756	314 vector. The codebook is used in CB_NSTAGES=3 stages in a successive
pascal@12756	315 refinement approach, and the resulting three code vector gains are
pascal@12756	316 encoded with 5-, 4-, and 3-bit scalar quantization, respectively.
pascal@12756	317
pascal@12756	318 The codebook search method employs noise shaping derived from the LPC
pascal@12756	319 filters, and the main decision criterion is to minimize the squared
pascal@12756	320 error between the target vector and the code vectors. Each code
pascal@12756	321 vector in this codebook comes from one of CB_EXPAND=2 codebook
pascal@12756	322 sections. The first section is filled with delayed, already encoded
pascal@12756	323 residual vectors. The code vectors of the second codebook section
pascal@12756	324 are constructed by predefined linear combinations of vectors in the
pascal@12756	325 first section of the codebook.
pascal@12756	326
pascal@12756	327 As codebook encoding with squared-error matching is known to produce
pascal@12756	328 a coded signal of less power than does the scalar quantized start
pascal@12756	329 state signal, a gain re-scaling method is implemented by a refined
pascal@12756	330 search for a better set of codebook gains in terms of power matching
pascal@12756	331 after encoding. This is done by searching for a higher value of the
pascal@12756	332 gain factor for the first stage codebook, as the subsequent stage
pascal@12756	333 codebook gains are scaled by the first stage gain.
pascal@12756	334
pascal@12756	335
pascal@12756	336
pascal@12756	337
pascal@12756	338 Andersen, et al. Experimental [Page 6]
pascal@12756	339
pascal@12756	340 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	341
pascal@12756	342
pascal@12756	343 2.2. Decoder
pascal@12756	344
pascal@12756	345 Typically for packet communications, a jitter buffer placed at the
pascal@12756	346 receiving end decides whether the packet containing an encoded signal
pascal@12756	347 block has been received or lost. This logic is not part of the codec
pascal@12756	348 described here. For each encoded signal block received the decoder
pascal@12756	349 performs a decoding. For each lost signal block, the decoder
pascal@12756	350 performs a PLC operation.
pascal@12756	351
pascal@12756	352 The decoding for each block starts by decoding and interpolating the
pascal@12756	353 LPC coefficients. Subsequently the start state is decoded.
pascal@12756	354
pascal@12756	355 For codebook-encoded segments, each segment is decoded by
pascal@12756	356 constructing the three code vectors given by the received codebook
pascal@12756	357 indices in the same way that the code vectors were constructed in the
pascal@12756	358 encoder. The three gain factors are also decoded and the resulting
pascal@12756	359 decoded signal is given by the sum of the three codebook vectors
pascal@12756	360 scaled with respective gain.
pascal@12756	361
pascal@12756	362 An enhancement algorithm is applied to the reconstructed excitation
pascal@12756	363 signal. This enhancement augments the periodicity of voiced speech
pascal@12756	364 regions. The enhancement is optimized under the constraint that the
pascal@12756	365 modification signal (defined as the difference between the enhanced
pascal@12756	366 excitation and the excitation signal prior to enhancement) has a
pascal@12756	367 short-time energy that does not exceed a preset fraction of the
pascal@12756	368 short-time energy of the excitation signal prior to enhancement.
pascal@12756	369
pascal@12756	370 A packet loss concealment (PLC) operation is easily embedded in the
pascal@12756	371 decoder. The PLC operation can, e.g., be based on repeating LPC
pascal@12756	372 filters and obtaining the LPC residual signal by using a long-term
pascal@12756	373 prediction estimate from previous residual blocks.
pascal@12756	374
pascal@12756	375 3. Encoder Principles
pascal@12756	376
pascal@12756	377 The following block diagram is an overview of all the components of
pascal@12756	378 the iLBC encoding procedure. The description of the blocks contains
pascal@12756	379 references to the section where that particular procedure is further
pascal@12756	380 described.
pascal@12756	381
pascal@12756	382
pascal@12756	383
pascal@12756	384
pascal@12756	385
pascal@12756	386
pascal@12756	387
pascal@12756	388
pascal@12756	389
pascal@12756	390
pascal@12756	391
pascal@12756	392
pascal@12756	393
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pascal@12756	396 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	397
pascal@12756	398
pascal@12756	399 +-----------+ +---------+ +---------+
pascal@12756	400 speech -> \| 1. Pre P \| -> \| 2. LPC \| -> \| 3. Ana \| ->
pascal@12756	401 +-----------+ +---------+ +---------+
pascal@12756	402
pascal@12756	403 +---------------+ +--------------+
pascal@12756	404 -> \| 4. Start Sel \| ->\| 5. Scalar Qu \| ->
pascal@12756	405 +---------------+ +--------------+
pascal@12756	406
pascal@12756	407 +--------------+ +---------------+
pascal@12756	408 -> \|6. CB Search \| -> \| 7. Packetize \| -> payload
pascal@12756	409 \| +--------------+ \| +---------------+
pascal@12756	410 ----<---------<------
pascal@12756	411 sub-frame 0..2/4 (20 ms/30 ms)
pascal@12756	412
pascal@12756	413 Figure 3.1. Flow chart of the iLBC encoder
pascal@12756	414
pascal@12756	415 1. Pre-process speech with a HP filter, if needed (section 3.1).
pascal@12756	416
pascal@12756	417 2. Compute LPC parameters, quantize, and interpolate (section 3.2).
pascal@12756	418
pascal@12756	419 3. Use analysis filters on speech to compute residual (section 3.3).
pascal@12756	420
pascal@12756	421 4. Select position of 57/58-sample start state (section 3.5).
pascal@12756	422
pascal@12756	423 5. Quantize the 57/58-sample start state with scalar quantization
pascal@12756	424 (section 3.5).
pascal@12756	425
pascal@12756	426 6. Search the codebook for each sub-frame. Start with 23/22 sample
pascal@12756	427 block, then encode sub-blocks forward in time, and then encode
pascal@12756	428 sub-blocks backward in time. For each block, the steps in Figure
pascal@12756	429 3.4 are performed (section 3.6).
pascal@12756	430
pascal@12756	431 7. Packetize the bits into the payload specified in Table 3.2.
pascal@12756	432
pascal@12756	433 The input to the encoder SHOULD be 16-bit uniform PCM sampled at 8
pascal@12756	434 kHz. Also it SHOULD be partitioned into blocks of BLOCKL=160/240
pascal@12756	435 samples. Each block input to the encoder is divided into NSUB=4/6
pascal@12756	436 consecutive sub-blocks of SUBL=40 samples each.
pascal@12756	437
pascal@12756	438
pascal@12756	439
pascal@12756	440
pascal@12756	441
pascal@12756	442
pascal@12756	443
pascal@12756	444
pascal@12756	445
pascal@12756	446
pascal@12756	447
pascal@12756	448
pascal@12756	449
pascal@12756	450 Andersen, et al. Experimental [Page 8]
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pascal@12756	452 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	453
pascal@12756	454
pascal@12756	455 0 39 79 119 159
pascal@12756	456 +---------------------------------------+
pascal@12756	457 \| 1 \| 2 \| 3 \| 4 \|
pascal@12756	458 +---------------------------------------+
pascal@12756	459 20 ms frame
pascal@12756	460
pascal@12756	461 0 39 79 119 159 199 239
pascal@12756	462 +-----------------------------------------------------------+
pascal@12756	463 \| 1 \| 2 \| 3 \| 4 \| 5 \| 6 \|
pascal@12756	464 +-----------------------------------------------------------+
pascal@12756	465 30 ms frame
pascal@12756	466 Figure 3.2. One input block to the encoder for 20 ms (with four sub-
pascal@12756	467 frames) and 30 ms (with six sub-frames).
pascal@12756	468
pascal@12756	469 3.1. Pre-processing
pascal@12756	470
pascal@12756	471 In some applications, the recorded speech signal contains DC level
pascal@12756	472 and/or 50/60 Hz noise. If these components have not been removed
pascal@12756	473 prior to the encoder call, they should be removed by a high-pass
pascal@12756	474 filter. A reference implementation of this, using a filter with a
pascal@12756	475 cutoff frequency of 90 Hz, can be found in Appendix A.28.
pascal@12756	476
pascal@12756	477 3.2. LPC Analysis and Quantization
pascal@12756	478
pascal@12756	479 The input to the LPC analysis module is a possibly high-pass filtered
pascal@12756	480 speech buffer, speech_hp, that contains 240/300 (LPC_LOOKBACK +
pascal@12756	481 BLOCKL = 80/60 + 160/240 = 240/300) speech samples, where samples 0
pascal@12756	482 through 79/59 are from the previous block and samples 80/60 through
pascal@12756	483 239/299 are from the current block. No look-ahead into the next
pascal@12756	484 block is used. For the very first block processed, the look-back
pascal@12756	485 samples are assumed to be zeros.
pascal@12756	486
pascal@12756	487 For each input block, the LPC analysis calculates one/two set(s) of
pascal@12756	488 LPC_FILTERORDER=10 LPC filter coefficients using the autocorrelation
pascal@12756	489 method and the Levinson-Durbin recursion. These coefficients are
pascal@12756	490 converted to the Line Spectrum Frequency representation. In the 20
pascal@12756	491 ms case, the single lsf set represents the spectral characteristics
pascal@12756	492 as measured at the center of the third sub-block. For 30 ms frames,
pascal@12756	493 the first set, lsf1, represents the spectral properties of the input
pascal@12756	494 signal at the center of the second sub-block, and the other set,
pascal@12756	495 lsf2, represents the spectral characteristics as measured at the
pascal@12756	496 center of the fifth sub-block. The details of the computation for 30
pascal@12756	497 ms frames are described in sections 3.2.1 through 3.2.6. Section
pascal@12756	498 3.2.7 explains how the LPC Analysis and Quantization differs for 20
pascal@12756	499 ms frames.
pascal@12756	500
pascal@12756	501
pascal@12756	502
pascal@12756	503
pascal@12756	504
pascal@12756	505
pascal@12756	506 Andersen, et al. Experimental [Page 9]
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pascal@12756	508 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	509
pascal@12756	510
pascal@12756	511 3.2.1. Computation of Autocorrelation Coefficients
pascal@12756	512
pascal@12756	513 The first step in the LPC analysis procedure is to calculate
pascal@12756	514 autocorrelation coefficients by using windowed speech samples. This
pascal@12756	515 windowing is the only difference in the LPC analysis procedure for
pascal@12756	516 the two sets of coefficients. For the first set, a 240-sample-long
pascal@12756	517 standard symmetric Hanning window is applied to samples 0 through 239
pascal@12756	518 of the input data. The first window, lpc_winTbl, is defined as
pascal@12756	519
pascal@12756	520 lpc_winTbl[i]= 0.5 * (1.0 - cos((2PI(i+1))/(BLOCKL+1)));
pascal@12756	521 i=0,...,119
pascal@12756	522 lpc_winTbl[i] = winTbl[BLOCKL - i - 1]; i=120,...,239
pascal@12756	523
pascal@12756	524 The windowed speech speech_hp_win1 is then obtained by multiplying
pascal@12756	525 the first 240 samples of the input speech buffer with the window
pascal@12756	526 coefficients:
pascal@12756	527
pascal@12756	528 speech_hp_win1[i] = speech_hp[i] * lpc_winTbl[i];
pascal@12756	529 i=0,...,BLOCKL-1
pascal@12756	530
pascal@12756	531 From these 240 windowed speech samples, 11 (LPC_FILTERORDER + 1)
pascal@12756	532 autocorrelation coefficients, acf1, are calculated:
pascal@12756	533
pascal@12756	534 acf1[lag] += speech_hp_win1[n] * speech_hp_win1[n + lag];
pascal@12756	535 lag=0,...,LPC_FILTERORDER; n=0,...,BLOCKL-lag-1
pascal@12756	536
pascal@12756	537 In order to make the analysis more robust against numerical precision
pascal@12756	538 problems, a spectral smoothing procedure is applied by windowing the
pascal@12756	539 autocorrelation coefficients before the LPC coefficients are
pascal@12756	540 computed. Also, a white noise floor is added to the autocorrelation
pascal@12756	541 function by multiplying coefficient zero by 1.0001 (40dB below the
pascal@12756	542 energy of the windowed speech signal). These two steps are
pascal@12756	543 implemented by multiplying the autocorrelation coefficients with the
pascal@12756	544 following window:
pascal@12756	545
pascal@12756	546 lpc_lagwinTbl[0] = 1.0001;
pascal@12756	547 lpc_lagwinTbl[i] = exp(-0.5 * ((2 * PI * 60.0 * i) /FS)^2);
pascal@12756	548 i=1,...,LPC_FILTERORDER
pascal@12756	549 where FS=8000 is the sampling frequency
pascal@12756	550
pascal@12756	551 Then, the windowed acf function acf1_win is obtained by
pascal@12756	552
pascal@12756	553 acf1_win[i] = acf1[i] * lpc_lagwinTbl[i];
pascal@12756	554 i=0,...,LPC_FILTERORDER
pascal@12756	555
pascal@12756	556 The second set of autocorrelation coefficients, acf2_win, are
pascal@12756	557 obtained in a similar manner. The window, lpc_asymwinTbl, is applied
pascal@12756	558 to samples 60 through 299, i.e., the entire current block. The
pascal@12756	559
pascal@12756	560
pascal@12756	561
pascal@12756	562 Andersen, et al. Experimental [Page 10]
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pascal@12756	564 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	565
pascal@12756	566
pascal@12756	567 window consists of two segments, the first (samples 0 to 219) being
pascal@12756	568 half a Hanning window with length 440 and the second a quarter of a
pascal@12756	569 cycle of a cosine wave. By using this asymmetric window, an LPC
pascal@12756	570 analysis centered in the fifth sub-block is obtained without the need
pascal@12756	571 for any look-ahead, which would add delay. The asymmetric window is
pascal@12756	572 defined as
pascal@12756	573
pascal@12756	574 lpc_asymwinTbl[i] = (sin(PI * (i + 1) / 441))^2; i=0,...,219
pascal@12756	575
pascal@12756	576 lpc_asymwinTbl[i] = cos((i - 220) * PI / 40); i=220,...,239
pascal@12756	577
pascal@12756	578 and the windowed speech is computed by
pascal@12756	579
pascal@12756	580 speech_hp_win2[i] = speech_hp[i + LPC_LOOKBACK] *
pascal@12756	581 lpc_asymwinTbl[i]; i=0,....BLOCKL-1
pascal@12756	582
pascal@12756	583 The windowed autocorrelation coefficients are then obtained in
pascal@12756	584 exactly the same way as for the first analysis instance.
pascal@12756	585
pascal@12756	586 The generation of the windows lpc_winTbl, lpc_asymwinTbl, and
pascal@12756	587 lpc_lagwinTbl are typically done in advance, and the arrays are
pascal@12756	588 stored in ROM rather than repeating the calculation for every block.
pascal@12756	589
pascal@12756	590 3.2.2. Computation of LPC Coefficients
pascal@12756	591
pascal@12756	592 From the 2 x 11 smoothed autocorrelation coefficients, acf1_win and
pascal@12756	593 acf2_win, the 2 x 11 LPC coefficients, lp1 and lp2, are calculated
pascal@12756	594 in the same way for both analysis locations by using the well known
pascal@12756	595 Levinson-Durbin recursion. The first LPC coefficient is always 1.0,
pascal@12756	596 resulting in ten unique coefficients.
pascal@12756	597
pascal@12756	598 After determining the LPC coefficients, a bandwidth expansion
pascal@12756	599 procedure is applied to smooth the spectral peaks in the
pascal@12756	600 short-term spectrum. The bandwidth addition is obtained by the
pascal@12756	601 following modification of the LPC coefficients:
pascal@12756	602
pascal@12756	603 lp1_bw[i] = lp1[i] * chirp^i; i=0,...,LPC_FILTERORDER
pascal@12756	604 lp2_bw[i] = lp2[i] * chirp^i; i=0,...,LPC_FILTERORDER
pascal@12756	605
pascal@12756	606 where "chirp" is a real number between 0 and 1. It is RECOMMENDED to
pascal@12756	607 use a value of 0.9.
pascal@12756	608
pascal@12756	609 3.2.3. Computation of LSF Coefficients from LPC Coefficients
pascal@12756	610
pascal@12756	611 Thus far, two sets of LPC coefficients that represent the short-term
pascal@12756	612 spectral characteristics of the speech signal for two different time
pascal@12756	613 locations within the current block have been determined. These
pascal@12756	614 coefficients SHOULD be quantized and interpolated. Before this is
pascal@12756	615
pascal@12756	616
pascal@12756	617
pascal@12756	618 Andersen, et al. Experimental [Page 11]
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pascal@12756	620 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	621
pascal@12756	622
pascal@12756	623 done, it is advantageous to convert the LPC parameters into another
pascal@12756	624 type of representation called Line Spectral Frequencies (LSF). The
pascal@12756	625 LSF parameters are used because they are better suited for
pascal@12756	626 quantization and interpolation than the regular LPC coefficients.
pascal@12756	627 Many computationally efficient methods for calculating the LSFs from
pascal@12756	628 the LPC coefficients have been proposed in the literature. The
pascal@12756	629 detailed implementation of one applicable method can be found in
pascal@12756	630 Appendix A.26. The two arrays of LSF coefficients obtained, lsf1 and
pascal@12756	631 lsf2, are of dimension 10 (LPC_FILTERORDER).
pascal@12756	632
pascal@12756	633 3.2.4. Quantization of LSF Coefficients
pascal@12756	634
pascal@12756	635 Because the LPC filters defined by the two sets of LSFs are also
pascal@12756	636 needed in the decoder, the LSF parameters need to be quantized and
pascal@12756	637 transmitted as side information. The total number of bits required
pascal@12756	638 to represent the quantization of the two LSF representations for one
pascal@12756	639 block of speech is 40, with 20 bits used for each of lsf1 and lsf2.
pascal@12756	640
pascal@12756	641 For computational and storage reasons, the LSF vectors are quantized
pascal@12756	642 using three-split vector quantization (VQ). That is, the LSF vectors
pascal@12756	643 are split into three sub-vectors that are each quantized with a
pascal@12756	644 regular VQ. The quantized versions of lsf1 and lsf2, qlsf1 and
pascal@12756	645 qlsf2, are obtained by using the same memoryless split VQ. The
pascal@12756	646 length of each of these two LSF vectors is 10, and they are split
pascal@12756	647 into three sub-vectors containing 3, 3, and 4 values, respectively.
pascal@12756	648
pascal@12756	649 For each of the sub-vectors, a separate codebook of quantized values
pascal@12756	650 has been designed with a standard VQ training method for a large
pascal@12756	651 database containing speech from a large number of speakers recorded
pascal@12756	652 under various conditions. The size of each of the three codebooks
pascal@12756	653 associated with the split definitions above is
pascal@12756	654
pascal@12756	655 int size_lsfCbTbl[LSF_NSPLIT] = {64,128,128};
pascal@12756	656
pascal@12756	657 The actual values of the vector quantization codebook that must be
pascal@12756	658 used can be found in the reference code of Appendix A. Both sets of
pascal@12756	659 LSF coefficients, lsf1 and lsf2, are quantized with a standard
pascal@12756	660 memoryless split vector quantization (VQ) structure using the squared
pascal@12756	661 error criterion in the LSF domain. The split VQ quantization
pascal@12756	662 consists of the following steps:
pascal@12756	663
pascal@12756	664 1) Quantize the first three LSF coefficients (1 - 3) with a VQ
pascal@12756	665 codebook of size 64.
pascal@12756	666 2) Quantize the next three LSF coefficients 4 - 6 with VQ a codebook
pascal@12756	667 of size 128.
pascal@12756	668 3) Quantize the last four LSF coefficients (7 - 10) with a VQ
pascal@12756	669 codebook of size 128.
pascal@12756	670
pascal@12756	671
pascal@12756	672
pascal@12756	673
pascal@12756	674 Andersen, et al. Experimental [Page 12]
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pascal@12756	676 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	677
pascal@12756	678
pascal@12756	679 This procedure, repeated for lsf1 and lsf2, gives six quantization
pascal@12756	680 indices and the quantized sets of LSF coefficients qlsf1 and qlsf2.
pascal@12756	681 Each set of three indices is encoded with 6 + 7 + 7 = 20 bits. The
pascal@12756	682 total number of bits used for LSF quantization in a block is thus 40
pascal@12756	683 bits.
pascal@12756	684
pascal@12756	685 3.2.5. Stability Check of LSF Coefficients
pascal@12756	686
pascal@12756	687 The LSF representation of the LPC filter has the convenient property
pascal@12756	688 that the coefficients are ordered by increasing value, i.e., lsf(n-1)
pascal@12756	689 < lsf(n), 0 < n < 10, if the corresponding synthesis filter is
pascal@12756	690 stable. As we are employing a split VQ scheme, it is possible that
pascal@12756	691 at the split boundaries the LSF coefficients are not ordered
pascal@12756	692 correctly and hence that the corresponding LP filter is unstable. To
pascal@12756	693 ensure that the filter used is stable, a stability check is performed
pascal@12756	694 for the quantized LSF vectors. If it turns out that the coefficients
pascal@12756	695 are not ordered appropriately (with a safety margin of 50 Hz to
pascal@12756	696 ensure that formant peaks are not too narrow), they will be moved
pascal@12756	697 apart. The detailed method for this can be found in Appendix A.40.
pascal@12756	698 The same procedure is performed in the decoder. This ensures that
pascal@12756	699 exactly the same LSF representations are used in both encoder and
pascal@12756	700 decoder.
pascal@12756	701
pascal@12756	702 3.2.6. Interpolation of LSF Coefficients
pascal@12756	703
pascal@12756	704 From the two sets of LSF coefficients that are computed for each
pascal@12756	705 block of speech, different LSFs are obtained for each sub-block by
pascal@12756	706 means of interpolation. This procedure is performed for the original
pascal@12756	707 LSFs (lsf1 and lsf2), as well as the quantized versions qlsf1 and
pascal@12756	708 qlsf2, as both versions are used in the encoder. Here follows a
pascal@12756	709 brief summary of the interpolation scheme; the details are found in
pascal@12756	710 the c-code of Appendix A. In the first sub-block, the average of the
pascal@12756	711 second LSF vector from the previous block and the first LSF vector in
pascal@12756	712 the current block is used. For sub-blocks two through five, the LSFs
pascal@12756	713 used are obtained by linear interpolation from lsf1 (and qlsf1) to
pascal@12756	714 lsf2 (and qlsf2), with lsf1 used in sub-block two and lsf2 in sub-
pascal@12756	715 block five. In the last sub-block, lsf2 is used. For the very first
pascal@12756	716 block it is assumed that the last LSF vector of the previous block is
pascal@12756	717 equal to a predefined vector, lsfmeanTbl, obtained by calculating the
pascal@12756	718 mean LSF vector of the LSF design database.
pascal@12756	719
pascal@12756	720 lsfmeanTbl[LPC_FILTERORDER] = {0.281738, 0.445801, 0.663330,
pascal@12756	721 0.962524, 1.251831, 1.533081, 1.850586, 2.137817,
pascal@12756	722 2.481445, 2.777344}
pascal@12756	723
pascal@12756	724
pascal@12756	725
pascal@12756	726
pascal@12756	727
pascal@12756	728
pascal@12756	729
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pascal@12756	732 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	733
pascal@12756	734
pascal@12756	735 The interpolation method is standard linear interpolation in the LSF
pascal@12756	736 domain. The interpolated LSF values are converted to LPC
pascal@12756	737 coefficients for each sub-block. The unquantized and quantized LPC
pascal@12756	738 coefficients form two sets of filters respectively. The unquantized
pascal@12756	739 analysis filter for sub-block k is defined as follows
pascal@12756	740
pascal@12756	741 ___
pascal@12756	742 \
pascal@12756	743 Ak(z)= 1 + > ak(i)*z^(-i)
pascal@12756	744 /__
pascal@12756	745 i=1...LPC_FILTERORDER
pascal@12756	746
pascal@12756	747 The quantized analysis filter for sub-block k is defined as follows
pascal@12756	748 ___
pascal@12756	749 \
pascal@12756	750 A~k(z)= 1 + > a~k(i)*z^(-i)
pascal@12756	751 /__
pascal@12756	752 i=1...LPC_FILTERORDER
pascal@12756	753
pascal@12756	754 A reference implementation of the lsf encoding is given in Appendix
pascal@12756	755 A.38. A reference implementation of the corresponding decoding can
pascal@12756	756 be found in Appendix A.36.
pascal@12756	757
pascal@12756	758 3.2.7. LPC Analysis and Quantization for 20 ms Frames
pascal@12756	759
pascal@12756	760 As previously stated, the codec only calculates one set of LPC
pascal@12756	761 parameters for the 20 ms frame size as opposed to two sets for 30 ms
pascal@12756	762 frames. A single set of autocorrelation coefficients is calculated
pascal@12756	763 on the LPC_LOOKBACK + BLOCKL = 80 + 160 = 240 samples. These samples
pascal@12756	764 are windowed with the asymmetric window lpc_asymwinTbl, centered over
pascal@12756	765 the third sub-frame, to form speech_hp_win. Autocorrelation
pascal@12756	766 coefficients, acf, are calculated on the 240 samples in speech_hp_win
pascal@12756	767 and then windowed exactly as in section 3.2.1 (resulting in
pascal@12756	768 acf_win).
pascal@12756	769
pascal@12756	770 This single set of windowed autocorrelation coefficients is used to
pascal@12756	771 calculate LPC coefficients, LSF coefficients, and quantized LSF
pascal@12756	772 coefficients in exactly the same manner as in sections 3.2.3 through
pascal@12756	773 3.2.4. As for the 30 ms frame size, the ten LSF coefficients are
pascal@12756	774 divided into three sub-vectors of size 3, 3, and 4 and quantized by
pascal@12756	775 using the same scheme and codebook as in section 3.2.4 to finally get
pascal@12756	776 3 quantization indices. The quantized LSF coefficients are
pascal@12756	777 stabilized with the algorithm described in section 3.2.5.
pascal@12756	778
pascal@12756	779 From the set of LSF coefficients computed for this block and those
pascal@12756	780 from the previous block, different LSFs are obtained for each sub-
pascal@12756	781 block by means of interpolation. The interpolation is done linearly
pascal@12756	782 in the LSF domain over the four sub-blocks, so that the n-th sub-
pascal@12756	783
pascal@12756	784
pascal@12756	785
pascal@12756	786 Andersen, et al. Experimental [Page 14]
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pascal@12756	789
pascal@12756	790
pascal@12756	791 frame uses the weight (4-n)/4 for the LSF from old frame and the
pascal@12756	792 weight n/4 of the LSF from the current frame. For the very first
pascal@12756	793 block the mean LSF, lsfmeanTbl, is used as the LSF from the previous
pascal@12756	794 block. Similarly as seen in section 3.2.6, both unquantized, A(z),
pascal@12756	795 and quantized, A~(z), analysis filters are calculated for each of the
pascal@12756	796 four sub-blocks.
pascal@12756	797
pascal@12756	798 3.3. Calculation of the Residual
pascal@12756	799
pascal@12756	800 The block of speech samples is filtered by the quantized and
pascal@12756	801 interpolated LPC analysis filters to yield the residual signal. In
pascal@12756	802 particular, the corresponding LPC analysis filter for each 40 sample
pascal@12756	803 sub-block is used to filter the speech samples for the same sub-
pascal@12756	804 block. The filter memory at the end of each sub-block is carried
pascal@12756	805 over to the LPC filter of the next sub-block. The signal at the
pascal@12756	806 output of each LP analysis filter constitutes the residual signal for
pascal@12756	807 the corresponding sub-block.
pascal@12756	808
pascal@12756	809 A reference implementation of the LPC analysis filters is given in
pascal@12756	810 Appendix A.10.
pascal@12756	811
pascal@12756	812 3.4. Perceptual Weighting Filter
pascal@12756	813
pascal@12756	814 In principle any good design of a perceptual weighting filter can be
pascal@12756	815 applied in the encoder without compromising this codec definition.
pascal@12756	816 However, it is RECOMMENDED to use the perceptual weighting filter Wk
pascal@12756	817 for sub-block k specified below:
pascal@12756	818
pascal@12756	819 Wk(z)=1/Ak(z/LPC_CHIRP_WEIGHTDENUM), where
pascal@12756	820 LPC_CHIRP_WEIGHTDENUM = 0.4222
pascal@12756	821
pascal@12756	822 This is a simple design with low complexity that is applied in the
pascal@12756	823 LPC residual domain. Here Ak(z) is the filter obtained for sub-block
pascal@12756	824 k from unquantized but interpolated LSF coefficients.
pascal@12756	825
pascal@12756	826 3.5. Start State Encoder
pascal@12756	827
pascal@12756	828 The start state is quantized by using a common 6-bit scalar quantizer
pascal@12756	829 for the block and a 3-bit scalar quantizer operating on scaled
pascal@12756	830 samples in the weighted speech domain. In the following we describe
pascal@12756	831 the state encoding in greater detail.
pascal@12756	832
pascal@12756	833
pascal@12756	834
pascal@12756	835
pascal@12756	836
pascal@12756	837
pascal@12756	838
pascal@12756	839
pascal@12756	840
pascal@12756	841
pascal@12756	842 Andersen, et al. Experimental [Page 15]
pascal@12756	843
pascal@12756	844 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	845
pascal@12756	846
pascal@12756	847 3.5.1. Start State Estimation
pascal@12756	848
pascal@12756	849 The two sub-blocks containing the start state are determined by
pascal@12756	850 finding the two consecutive sub-blocks in the block having the
pascal@12756	851 highest power. Advantageously, down-weighting is used in the
pascal@12756	852 beginning and end of the sub-frames, i.e., the following measure is
pascal@12756	853 computed (NSUB=4/6 for 20/30 ms frame size):
pascal@12756	854
pascal@12756	855 nsub=1,...,NSUB-1
pascal@12756	856 ssqn[nsub] = 0.0;
pascal@12756	857 for (i=(nsub-1)SUBL; i<(nsub-1)SUBL+5; i++)
pascal@12756	858 ssqn[nsub] += sampEn_win[i-(nsub-1)SUBL]
pascal@12756	859 residual[i]*residual[i];
pascal@12756	860 for (i=(nsub-1)SUBL+5; i<(nsub+1)SUBL-5; i++)
pascal@12756	861 ssqn[nsub] += residual[i]*residual[i];
pascal@12756	862 for (i=(nsub+1)SUBL-5; i<(nsub+1)SUBL; i++)
pascal@12756	863 ssqn[nsub] += sampEn_win[(nsub+1)SUBL-i-1]
pascal@12756	864 residual[i]*residual[i];
pascal@12756	865
pascal@12756	866 where sampEn_win[5]={1/6, 2/6, 3/6, 4/6, 5/6}; MAY be used. The
pascal@12756	867 sub-frame number corresponding to the maximum value of
pascal@12756	868 ssqEn_win[nsub-1]*ssqn[nsub] is selected as the start state
pascal@12756	869 indicator. A weighting of ssqEn_win[]={0.8,0.9,1.0,0.9,0.8} for 30
pascal@12756	870 ms frames and ssqEn_win[]={0.9,1.0,0.9} for 20 ms frames; MAY
pascal@12756	871 advantageously be used to bias the start state towards the middle of
pascal@12756	872 the frame.
pascal@12756	873
pascal@12756	874 For 20 ms frames there are three possible positions for the two-sub-
pascal@12756	875 block length maximum power segment; the start state position is
pascal@12756	876 encoded with 2 bits. The start state position, start, MUST be
pascal@12756	877 encoded as
pascal@12756	878
pascal@12756	879 start=1: start state in sub-frame 0 and 1
pascal@12756	880 start=2: start state in sub-frame 1 and 2
pascal@12756	881 start=3: start state in sub-frame 2 and 3
pascal@12756	882
pascal@12756	883 For 30 ms frames there are five possible positions of the two-sub-
pascal@12756	884 block length maximum power segment, the start state position is
pascal@12756	885 encoded with 3 bits. The start state position, start, MUST be
pascal@12756	886 encoded as
pascal@12756	887
pascal@12756	888 start=1: start state in sub-frame 0 and 1
pascal@12756	889 start=2: start state in sub-frame 1 and 2
pascal@12756	890 start=3: start state in sub-frame 2 and 3
pascal@12756	891 start=4: start state in sub-frame 3 and 4
pascal@12756	892 start=5: start state in sub-frame 4 and 5
pascal@12756	893
pascal@12756	894
pascal@12756	895
pascal@12756	896
pascal@12756	897
pascal@12756	898 Andersen, et al. Experimental [Page 16]
pascal@12756	899
pascal@12756	900 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	901
pascal@12756	902
pascal@12756	903 Hence, in both cases, index 0 is not used. In order to shorten the
pascal@12756	904 start state for bit rate efficiency, the start state is brought down
pascal@12756	905 to STATE_SHORT_LEN=57 samples for 20 ms frames and STATE_SHORT_LEN=58
pascal@12756	906 samples for 30 ms frames. The power of the first 23/22 and last
pascal@12756	907 23/22 samples of the two sub-frame blocks identified above is
pascal@12756	908 computed as the sum of the squared signal sample values, and the
pascal@12756	909 23/22-sample segment with the lowest power is excluded from the start
pascal@12756	910 state. One bit is transmitted to indicate which of the two possible
pascal@12756	911 57/58 sample segments is used. The start state position within the
pascal@12756	912 two sub-frames determined above, state_first, MUST be encoded as
pascal@12756	913
pascal@12756	914 state_first=1: start state is first STATE_SHORT_LEN samples
pascal@12756	915 state_first=0: start state is last STATE_SHORT_LEN samples
pascal@12756	916
pascal@12756	917 3.5.2. All-Pass Filtering and Scale Quantization
pascal@12756	918
pascal@12756	919 The block of residual samples in the start state is first filtered by
pascal@12756	920 an all-pass filter with the quantized LPC coefficients as denominator
pascal@12756	921 and reversed quantized LPC coefficients as numerator. The purpose of
pascal@12756	922 this phase-dispersion filter is to get a more even distribution of
pascal@12756	923 the sample values in the residual signal. The filtering is performed
pascal@12756	924 by circular convolution, where the initial filter memory is set to
pascal@12756	925 zero.
pascal@12756	926
pascal@12756	927 res(0..(STATE_SHORT_LEN-1)) = uncoded start state residual
pascal@12756	928 res((STATE_SHORT_LEN)..(2*STATE_SHORT_LEN-1)) = 0
pascal@12756	929
pascal@12756	930 Pk(z) = A~rk(z)/A~k(z), where
pascal@12756	931 ___
pascal@12756	932 \
pascal@12756	933 A~rk(z)= z^(-LPC_FILTERORDER)+>a~k(i+1)*z^(i-(LPC_FILTERORDER-1))
pascal@12756	934 /__
pascal@12756	935 i=0...(LPC_FILTERORDER-1)
pascal@12756	936
pascal@12756	937 and A~k(z) is taken from the block where the start state begins
pascal@12756	938
pascal@12756	939 res -> Pk(z) -> filtered
pascal@12756	940
pascal@12756	941 ccres(k) = filtered(k) + filtered(k+STATE_SHORT_LEN),
pascal@12756	942 k=0..(STATE_SHORT_LEN-1)
pascal@12756	943
pascal@12756	944 The all-pass filtered block is searched for its largest magnitude
pascal@12756	945 sample. The 10-logarithm of this magnitude is quantized with a 6-bit
pascal@12756	946 quantizer, state_frgqTbl, by finding the nearest representation.
pascal@12756	947
pascal@12756	948
pascal@12756	949
pascal@12756	950
pascal@12756	951
pascal@12756	952
pascal@12756	953
pascal@12756	954 Andersen, et al. Experimental [Page 17]
pascal@12756	955
pascal@12756	956 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	957
pascal@12756	958
pascal@12756	959 This results in an index, idxForMax, corresponding to a quantized
pascal@12756	960 value, qmax. The all-pass filtered residual samples in the block are
pascal@12756	961 then multiplied with a scaling factor scal=4.5/(10^qmax) to yield
pascal@12756	962 normalized samples.
pascal@12756	963
pascal@12756	964 state_frgqTbl[64] = {1.000085, 1.071695, 1.140395, 1.206868,
pascal@12756	965 1.277188, 1.351503, 1.429380, 1.500727, 1.569049,
pascal@12756	966 1.639599, 1.707071, 1.781531, 1.840799, 1.901550,
pascal@12756	967 1.956695, 2.006750, 2.055474, 2.102787, 2.142819,
pascal@12756	968 2.183592, 2.217962, 2.257177, 2.295739, 2.332967,
pascal@12756	969 2.369248, 2.402792, 2.435080, 2.468598, 2.503394,
pascal@12756	970 2.539284, 2.572944, 2.605036, 2.636331, 2.668939,
pascal@12756	971 2.698780, 2.729101, 2.759786, 2.789834, 2.818679,
pascal@12756	972 2.848074, 2.877470, 2.906899, 2.936655, 2.967804,
pascal@12756	973 3.000115, 3.033367, 3.066355, 3.104231, 3.141499,
pascal@12756	974 3.183012, 3.222952, 3.265433, 3.308441, 3.350823,
pascal@12756	975 3.395275, 3.442793, 3.490801, 3.542514, 3.604064,
pascal@12756	976 3.666050, 3.740994, 3.830749, 3.938770, 4.101764}
pascal@12756	977
pascal@12756	978 3.5.3. Scalar Quantization
pascal@12756	979
pascal@12756	980 The normalized samples are quantized in the perceptually weighted
pascal@12756	981 speech domain by a sample-by-sample scalar DPCM quantization as
pascal@12756	982 depicted in Figure 3.3. Each sample in the block is filtered by a
pascal@12756	983 weighting filter Wk(z), specified in section 3.4, to form a weighted
pascal@12756	984 speech sample x[n]. The target sample d[n] is formed by subtracting
pascal@12756	985 a predicted sample y[n], where the prediction filter is given by
pascal@12756	986
pascal@12756	987 Pk(z) = 1 - 1 / Wk(z).
pascal@12756	988
pascal@12756	989 +-------+ x[n] + d[n] +-----------+ u[n]
pascal@12756	990 residual -->\| Wk(z) \|-------->(+)---->\| Quantizer \|------> quantized
pascal@12756	991 +-------+ - /\|\ +-----------+ \| residual
pascal@12756	992 \| \\|/
pascal@12756	993 y[n] +--------------------->(+)
pascal@12756	994 \| \|
pascal@12756	995 \| +------+ \|
pascal@12756	996 +--------\| Pk(z)\|<------+
pascal@12756	997 +------+
pascal@12756	998
pascal@12756	999 Figure 3.3. Quantization of start state samples by DPCM in weighted
pascal@12756	1000 speech domain.
pascal@12756	1001
pascal@12756	1002 The coded state sample u[n] is obtained by quantizing d[n] with a 3-
pascal@12756	1003 bit quantizer with quantization table state_sq3Tbl.
pascal@12756	1004
pascal@12756	1005 state_sq3Tbl[8] = {-3.719849, -2.177490, -1.130005, -0.309692,
pascal@12756	1006 0.444214, 1.329712, 2.436279, 3.983887}
pascal@12756	1007
pascal@12756	1008
pascal@12756	1009
pascal@12756	1010 Andersen, et al. Experimental [Page 18]
pascal@12756	1011
pascal@12756	1012 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1013
pascal@12756	1014
pascal@12756	1015 The quantized samples are transformed back to the residual domain by
pascal@12756	1016 1) scaling with 1/scal; 2) time-reversing the scaled samples; 3)
pascal@12756	1017 filtering the time-reversed samples by the same all-pass filter, as
pascal@12756	1018 in section 3.5.2, by using circular convolution; and 4) time-
pascal@12756	1019 reversing the filtered samples. (More detail is in section 4.2.)
pascal@12756	1020
pascal@12756	1021 A reference implementation of the start-state encoding can be found
pascal@12756	1022 in Appendix A.46.
pascal@12756	1023
pascal@12756	1024 3.6. Encoding the Remaining Samples
pascal@12756	1025
pascal@12756	1026 A dynamic codebook is used to encode 1) the 23/22 remaining samples
pascal@12756	1027 in the two sub-blocks containing the start state; 2) the sub-blocks
pascal@12756	1028 after the start state in time; and 3) the sub-blocks before the start
pascal@12756	1029 state in time. Thus, the encoding target can be either the 23/22
pascal@12756	1030 samples remaining of the 2 sub-blocks containing the start state, or
pascal@12756	1031 a 40-sample sub-block. This target can consist of samples that are
pascal@12756	1032 indexed forward in time or backward in time, depending on the
pascal@12756	1033 location of the start state. The length of the target is denoted by
pascal@12756	1034 lTarget.
pascal@12756	1035
pascal@12756	1036 The coding is based on an adaptive codebook that is built from a
pascal@12756	1037 codebook memory that contains decoded LPC excitation samples from the
pascal@12756	1038 already encoded part of the block. These samples are indexed in the
pascal@12756	1039 same time direction as is the target vector and end at the sample
pascal@12756	1040 instant prior to the first sample instant represented in the target
pascal@12756	1041 vector. The codebook memory has length lMem, which is equal to
pascal@12756	1042 CB_MEML=147 for the two/four 40-sample sub-blocks and 85 for the
pascal@12756	1043 23/22-sample sub-block.
pascal@12756	1044
pascal@12756	1045 The following figure shows an overview of the encoding procedure.
pascal@12756	1046
pascal@12756	1047 +------------+ +---------------+ +-------------+
pascal@12756	1048 -> \| 1. Decode \| -> \| 2. Mem setup \| -> \| 3. Perc. W. \| ->
pascal@12756	1049 +------------+ +---------------+ +-------------+
pascal@12756	1050
pascal@12756	1051 +------------+ +-----------------+
pascal@12756	1052 -> \| 4. Search \| -> \| 5. Upd. Target \| ------------------>
pascal@12756	1053 \| +------------+ +------------------ \|
pascal@12756	1054 ----<-------------<-----------<----------
pascal@12756	1055 stage=0..2
pascal@12756	1056
pascal@12756	1057 +----------------+
pascal@12756	1058 -> \| 6. Recalc G[0] \| ---------------> gains and CB indices
pascal@12756	1059 +----------------+
pascal@12756	1060
pascal@12756	1061 Figure 3.4. Flow chart of the codebook search in the iLBC encoder.
pascal@12756	1062
pascal@12756	1063
pascal@12756	1064
pascal@12756	1065
pascal@12756	1066 Andersen, et al. Experimental [Page 19]
pascal@12756	1067
pascal@12756	1068 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1069
pascal@12756	1070
pascal@12756	1071 1. Decode the part of the residual that has been encoded so far,
pascal@12756	1072 using the codebook without perceptual weighting.
pascal@12756	1073
pascal@12756	1074 2. Set up the memory by taking data from the decoded residual. This
pascal@12756	1075 memory is used to construct codebooks. For blocks preceding the
pascal@12756	1076 start state, both the decoded residual and the target are time
pascal@12756	1077 reversed (section 3.6.1).
pascal@12756	1078 3. Filter the memory + target with the perceptual weighting filter
pascal@12756	1079 (section 3.6.2).
pascal@12756	1080
pascal@12756	1081 4. Search for the best match between the target and the codebook
pascal@12756	1082 vector. Compute the optimal gain for this match and quantize that
pascal@12756	1083 gain (section 3.6.4).
pascal@12756	1084
pascal@12756	1085 5. Update the perceptually weighted target by subtracting the
pascal@12756	1086 contribution from the selected codebook vector from the
pascal@12756	1087 perceptually weighted memory (quantized gain times selected
pascal@12756	1088 vector). Repeat 4 and 5 for the two additional stages.
pascal@12756	1089
pascal@12756	1090 6. Calculate the energy loss due to encoding of the residual. If
pascal@12756	1091 needed, compensate for this loss by an upscaling and
pascal@12756	1092 requantization of the gain for the first stage (section 3.7).
pascal@12756	1093
pascal@12756	1094 The following sections provide an in-depth description of the
pascal@12756	1095 different blocks of Figure 3.4.
pascal@12756	1096
pascal@12756	1097 3.6.1. Codebook Memory
pascal@12756	1098
pascal@12756	1099 The codebook memory is based on the already encoded sub-blocks, so
pascal@12756	1100 the available data for encoding increases for each new sub-block that
pascal@12756	1101 has been encoded. Until enough sub-blocks have been encoded to fill
pascal@12756	1102 the codebook memory with data, it is padded with zeros. The
pascal@12756	1103 following figure shows an example of the order in which the sub-
pascal@12756	1104 blocks are encoded for the 30 ms frame size if the start state is
pascal@12756	1105 located in the last 58 samples of sub-block 2 and 3.
pascal@12756	1106
pascal@12756	1107 +-----------------------------------------------------+
pascal@12756	1108 \| 5 \| 1 \|///\|////////\| 2 \| 3 \| 4 \|
pascal@12756	1109 +-----------------------------------------------------+
pascal@12756	1110
pascal@12756	1111 Figure 3.5. The order from 1 to 5 in which the sub-blocks are
pascal@12756	1112 encoded. The slashed area is the start state.
pascal@12756	1113
pascal@12756	1114
pascal@12756	1115
pascal@12756	1116
pascal@12756	1117
pascal@12756	1118
pascal@12756	1119
pascal@12756	1120
pascal@12756	1121
pascal@12756	1122 Andersen, et al. Experimental [Page 20]
pascal@12756	1123
pascal@12756	1124 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1125
pascal@12756	1126
pascal@12756	1127 The first target sub-block to be encoded is number 1, and the
pascal@12756	1128 corresponding codebook memory is shown in the following figure. As
pascal@12756	1129 the target vector comes before the start state in time, the codebook
pascal@12756	1130 memory and target vector are time reversed; thus, after the block has
pascal@12756	1131 been time reversed the search algorithm can be reused. As only the
pascal@12756	1132 start state has been encoded so far, the last samples of the codebook
pascal@12756	1133 memory are padded with zeros.
pascal@12756	1134
pascal@12756	1135 +-------------------------
pascal@12756	1136 \|zeros\|\\\\\\\\\|\\\\\| 1 \|
pascal@12756	1137 +-------------------------
pascal@12756	1138
pascal@12756	1139 Figure 3.6. The codebook memory, length lMem=85 samples, and the
pascal@12756	1140 target vector 1, length 22 samples.
pascal@12756	1141
pascal@12756	1142 The next step is to encode sub-block 2 by using the memory that now
pascal@12756	1143 has increased since sub-block 1 has been encoded. The following
pascal@12756	1144 figure shows the codebook memory for encoding of sub-block 2.
pascal@12756	1145
pascal@12756	1146 +-----------------------------------
pascal@12756	1147 \| zeros \| 1 \|///\|////////\| 2 \|
pascal@12756	1148 +-----------------------------------
pascal@12756	1149
pascal@12756	1150 Figure 3.7. The codebook memory, length lMem=147 samples, and the
pascal@12756	1151 target vector 2, length 40 samples.
pascal@12756	1152
pascal@12756	1153 The next step is to encode sub-block 3 by using the memory which has
pascal@12756	1154 been increased yet again since sub-blocks 1 and 2 have been encoded,
pascal@12756	1155 but the sub-block still has to be padded with a few zeros. The
pascal@12756	1156 following figure shows the codebook memory for encoding of sub-block
pascal@12756	1157 3.
pascal@12756	1158
pascal@12756	1159 +------------------------------------------
pascal@12756	1160 \|zeros\| 1 \|///\|////////\| 2 \| 3 \|
pascal@12756	1161 +------------------------------------------
pascal@12756	1162
pascal@12756	1163 Figure 3.8. The codebook memory, length lMem=147 samples, and the
pascal@12756	1164 target vector 3, length 40 samples.
pascal@12756	1165
pascal@12756	1166 The next step is to encode sub-block 4 by using the memory which now
pascal@12756	1167 has increased yet again since sub-blocks 1, 2, and 3 have been
pascal@12756	1168 encoded. This time, the memory does not have to be padded with
pascal@12756	1169 zeros. The following figure shows the codebook memory for encoding
pascal@12756	1170 of sub-block 4.
pascal@12756	1171
pascal@12756	1172
pascal@12756	1173
pascal@12756	1174
pascal@12756	1175
pascal@12756	1176
pascal@12756	1177
pascal@12756	1178 Andersen, et al. Experimental [Page 21]
pascal@12756	1179
pascal@12756	1180 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1181
pascal@12756	1182
pascal@12756	1183 +------------------------------------------
pascal@12756	1184 \|1\|///\|////////\| 2 \| 3 \| 4 \|
pascal@12756	1185 +------------------------------------------
pascal@12756	1186
pascal@12756	1187 Figure 3.9. The codebook memory, length lMem=147 samples, and the
pascal@12756	1188 target vector 4, length 40 samples.
pascal@12756	1189
pascal@12756	1190 The final target sub-block to be encoded is number 5, and the
pascal@12756	1191 following figure shows the corresponding codebook memory. As the
pascal@12756	1192 target vector comes before the start state in time, the codebook
pascal@12756	1193 memory and target vector are time reversed.
pascal@12756	1194
pascal@12756	1195 +-------------------------------------------
pascal@12756	1196 \| 3 \| 2 \|\\\\\\\\\|\\\\\| 1 \| 5 \|
pascal@12756	1197 +-------------------------------------------
pascal@12756	1198
pascal@12756	1199 Figure 3.10. The codebook memory, length lMem=147 samples, and the
pascal@12756	1200 target vector 5, length 40 samples.
pascal@12756	1201
pascal@12756	1202 For the case of 20 ms frames, the encoding procedure looks almost
pascal@12756	1203 exactly the same. The only difference is that the size of the start
pascal@12756	1204 state is 57 samples and that there are only three sub-blocks to be
pascal@12756	1205 encoded. The encoding order is the same as above, starting with the
pascal@12756	1206 23-sample target and then encoding the two remaining 40-sample sub-
pascal@12756	1207 blocks, first going forward in time and then going backward in time
pascal@12756	1208 relative to the start state.
pascal@12756	1209
pascal@12756	1210 3.6.2. Perceptual Weighting of Codebook Memory and Target
pascal@12756	1211
pascal@12756	1212 To provide a perceptual weighting of the coding error, a
pascal@12756	1213 concatenation of the codebook memory and the target to be coded is
pascal@12756	1214 all-pole filtered with the perceptual weighting filter specified in
pascal@12756	1215 section 3.4. The filter state of the weighting filter is set to
pascal@12756	1216 zero.
pascal@12756	1217
pascal@12756	1218 in(0..(lMem-1)) = unweighted codebook memory
pascal@12756	1219 in(lMem..(lMem+lTarget-1)) = unweighted target signal
pascal@12756	1220
pascal@12756	1221
pascal@12756	1222 in -> Wk(z) -> filtered,
pascal@12756	1223 where Wk(z) is taken from the sub-block of the target
pascal@12756	1224
pascal@12756	1225 weighted codebook memory = filtered(0..(lMem-1))
pascal@12756	1226 weighted target signal = filtered(lMem..(lMem+lTarget-1))
pascal@12756	1227
pascal@12756	1228 The codebook search is done with the weighted codebook memory and the
pascal@12756	1229 weighted target, whereas the decoding and the codebook memory update
pascal@12756	1230 uses the unweighted codebook memory.
pascal@12756	1231
pascal@12756	1232
pascal@12756	1233
pascal@12756	1234 Andersen, et al. Experimental [Page 22]
pascal@12756	1235
pascal@12756	1236 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1237
pascal@12756	1238
pascal@12756	1239 3.6.3. Codebook Creation
pascal@12756	1240
pascal@12756	1241 The codebook for the search is created from the perceptually weighted
pascal@12756	1242 codebook memory. It consists of two sections, where the first is
pascal@12756	1243 referred to as the base codebook and the second as the expanded
pascal@12756	1244 codebook, as it is created by linear combinations of the first. Each
pascal@12756	1245 of these two sections also has a subsection referred to as the
pascal@12756	1246 augmented codebook. The augmented codebook is only created and used
pascal@12756	1247 for the coding of the 40-sample sub-blocks and not for the 23/22-
pascal@12756	1248 sample sub-block case. The codebook size used for the different
pascal@12756	1249 sub-blocks and different stages are summarized in the table below.
pascal@12756	1250
pascal@12756	1251 Stage
pascal@12756	1252 1 2 & 3
pascal@12756	1253 --------------------------------------------
pascal@12756	1254 22 128 (64+0)2 128 (64+0)2
pascal@12756	1255 Sub- 1:st 40 256 (108+20)2 128 (44+20)2
pascal@12756	1256 Blocks 2:nd 40 256 (108+20)2 256 (108+20)2
pascal@12756	1257 3:rd 40 256 (108+20)2 256 (108+20)2
pascal@12756	1258 4:th 40 256 (108+20)2 256 (108+20)2
pascal@12756	1259
pascal@12756	1260 Table 3.1. Codebook sizes for the 30 ms mode.
pascal@12756	1261
pascal@12756	1262 Table 3.1 shows the codebook size for the different sub-blocks and
pascal@12756	1263 stages for 30 ms frames. Inside the parentheses it shows how the
pascal@12756	1264 number of codebook vectors is distributed, within the two sections,
pascal@12756	1265 between the base/expanded codebook and the augmented base/expanded
pascal@12756	1266 codebook. It should be interpreted in the following way:
pascal@12756	1267 (base/expanded cb + augmented base/expanded cb). The total number of
pascal@12756	1268 codebook vectors for a specific sub-block and stage is given by the
pascal@12756	1269 following formula:
pascal@12756	1270
pascal@12756	1271 Tot. cb vectors = base cb + aug. base cb + exp. cb + aug. exp. cb
pascal@12756	1272
pascal@12756	1273 The corresponding values to Figure 3.1 for 20 ms frames are only
pascal@12756	1274 slightly modified. The short sub-block is 23 instead of 22 samples,
pascal@12756	1275 and the 3:rd and 4:th sub-frame are not present.
pascal@12756	1276
pascal@12756	1277 3.6.3.1. Creation of a Base Codebook
pascal@12756	1278
pascal@12756	1279 The base codebook is given by the perceptually weighted codebook
pascal@12756	1280 memory that is mentioned in section 3.5.3. The different codebook
pascal@12756	1281 vectors are given by sliding a window of length 23/22 or 40, given by
pascal@12756	1282 variable lTarget, over the lMem-long perceptually weighted codebook
pascal@12756	1283 memory. The indices are ordered so that the codebook vector
pascal@12756	1284 containing sample (lMem-lTarget-n) to (lMem-n-1) of the codebook
pascal@12756	1285
pascal@12756	1286
pascal@12756	1287
pascal@12756	1288
pascal@12756	1289
pascal@12756	1290 Andersen, et al. Experimental [Page 23]
pascal@12756	1291
pascal@12756	1292 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1293
pascal@12756	1294
pascal@12756	1295 memory vector has index n, where n=0..lMem-lTarget. Thus the total
pascal@12756	1296 number of base codebook vectors is lMem-lTarget+1, and the indices
pascal@12756	1297 are ordered from sample delay lTarget (23/22 or 40) to lMem+1 (86 or
pascal@12756	1298 148).
pascal@12756	1299
pascal@12756	1300 3.6.3.2. Codebook Expansion
pascal@12756	1301
pascal@12756	1302 The base codebook is expanded by a factor of 2, creating an
pascal@12756	1303 additional section in the codebook. This new section is obtained by
pascal@12756	1304 filtering the base codebook, base_cb, with a FIR filter with filter
pascal@12756	1305 length CB_FILTERLEN=8. The construction of the expanded codebook
pascal@12756	1306 compensates for the delay of four samples introduced by the FIR
pascal@12756	1307 filter.
pascal@12756	1308
pascal@12756	1309 cbfiltersTbl[CB_FILTERLEN]={-0.033691, 0.083740, -0.144043,
pascal@12756	1310 0.713379, 0.806152, -0.184326,
pascal@12756	1311 0.108887, -0.034180};
pascal@12756	1312
pascal@12756	1313 ___
pascal@12756	1314 \
pascal@12756	1315 exp_cb(k)= + > cbfiltersTbl(i)*x(k-i+4)
pascal@12756	1316 /__
pascal@12756	1317 i=0...(LPC_FILTERORDER-1)
pascal@12756	1318
pascal@12756	1319 where x(j) = base_cb(j) for j=0..lMem-1 and 0 otherwise
pascal@12756	1320
pascal@12756	1321 The individual codebook vectors of the new filtered codebook, exp_cb,
pascal@12756	1322 and their indices are obtained in the same fashion as described above
pascal@12756	1323 for the base codebook.
pascal@12756	1324
pascal@12756	1325 3.6.3.3. Codebook Augmentation
pascal@12756	1326
pascal@12756	1327 For cases where encoding entire sub-blocks, i.e., cbveclen=40, the
pascal@12756	1328 base and expanded codebooks are augmented to increase codebook
pascal@12756	1329 richness. The codebooks are augmented by vectors produced by
pascal@12756	1330 interpolation of segments. The base and expanded codebook,
pascal@12756	1331 constructed above, consists of vectors corresponding to sample delays
pascal@12756	1332 in the range from cbveclen to lMem. The codebook augmentation
pascal@12756	1333 attempts to augment these codebooks with vectors corresponding to
pascal@12756	1334 sample delays from 20 to 39. However, not all of these samples are
pascal@12756	1335 present in the base codebook and expanded codebook, respectively.
pascal@12756	1336 Therefore, the augmentation vectors are constructed as linear
pascal@12756	1337 combinations between samples corresponding to sample delays in the
pascal@12756	1338 range 20 to 39. The general idea of this procedure is presented in
pascal@12756	1339 the following figures and text. The procedure is performed for both
pascal@12756	1340 the base codebook and the expanded codebook.
pascal@12756	1341
pascal@12756	1342
pascal@12756	1343
pascal@12756	1344
pascal@12756	1345
pascal@12756	1346 Andersen, et al. Experimental [Page 24]
pascal@12756	1347
pascal@12756	1348 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1349
pascal@12756	1350
pascal@12756	1351 - - ------------------------\|
pascal@12756	1352 codebook memory \|
pascal@12756	1353 - - ------------------------\|
pascal@12756	1354 \|-5-\|---15---\|-5-\|
pascal@12756	1355 pi pp po
pascal@12756	1356
pascal@12756	1357 \| \| Codebook vector
pascal@12756	1358 \|---15---\|-5-\|-----20-----\| <- corresponding to
pascal@12756	1359 i ii iii sample delay 20
pascal@12756	1360
pascal@12756	1361 Figure 3.11. Generation of the first augmented codebook.
pascal@12756	1362
pascal@12756	1363 Figure 3.11 shows the codebook memory with pointers pi, pp, and po,
pascal@12756	1364 where pi points to sample 25, pp to sample 20, and po to sample 5.
pascal@12756	1365 Below the codebook memory, the augmented codebook vector
pascal@12756	1366 corresponding to sample delay 20 is drawn. Segment i consists of
pascal@12756	1367 fifteen samples from pointer pp and forward in time. Segment ii
pascal@12756	1368 consists of five interpolated samples from pi and forward and from po
pascal@12756	1369 and forward. The samples are linearly interpolated with weights
pascal@12756	1370 [0.0, 0.2, 0.4, 0.6, 0.8] for pi and weights [1.0, 0.8, 0.6, 0.4,
pascal@12756	1371 0.2] for po. Segment iii consists of twenty samples from pp and
pascal@12756	1372 forward. The augmented codebook vector corresponding to sample delay
pascal@12756	1373 21 is produced by moving pointers pp and pi one sample backward in
pascal@12756	1374 time. This gives us the following figure.
pascal@12756	1375
pascal@12756	1376 - - ------------------------\|
pascal@12756	1377 codebook memory \|
pascal@12756	1378 - - ------------------------\|
pascal@12756	1379 \|-5-\|---16---\|-5-\|
pascal@12756	1380 pi pp po
pascal@12756	1381
pascal@12756	1382 \| \| Codebook vector
pascal@12756	1383 \|---16---\|-5-\|-----19-----\| <- corresponding to
pascal@12756	1384 i ii iii sample delay 21
pascal@12756	1385
pascal@12756	1386 Figure 3.12. Generation of the second augmented codebook.
pascal@12756	1387
pascal@12756	1388 Figure 3.12 shows the codebook memory with pointers pi, pp and po
pascal@12756	1389 where pi points to sample 26, pp to sample 21, and po to sample 5.
pascal@12756	1390 Below the codebook memory, the augmented codebook vector
pascal@12756	1391 corresponding to sample delay 21 is drawn. Segment i now consists of
pascal@12756	1392 sixteen samples from pp and forward. Segment ii consists of five
pascal@12756	1393 interpolated samples from pi and forward and from po and forward, and
pascal@12756	1394 the interpolation weights are the same throughout the procedure.
pascal@12756	1395 Segment iii consists of nineteen samples from pp and forward. The
pascal@12756	1396 same procedure of moving the two pointers is continued until the last
pascal@12756	1397 augmented vector corresponding to sample delay 39 has been created.
pascal@12756	1398 This gives a total of twenty new codebook vectors to each of the two
pascal@12756	1399
pascal@12756	1400
pascal@12756	1401
pascal@12756	1402 Andersen, et al. Experimental [Page 25]
pascal@12756	1403
pascal@12756	1404 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1405
pascal@12756	1406
pascal@12756	1407 sections. Thus the total number of codebook vectors for each of the
pascal@12756	1408 two sections, when including the augmented codebook, becomes lMem-
pascal@12756	1409 SUBL+1+SUBL/2. This is provided that augmentation is evoked, i.e.,
pascal@12756	1410 that lTarget=SUBL.
pascal@12756	1411
pascal@12756	1412 3.6.4. Codebook Search
pascal@12756	1413
pascal@12756	1414 The codebook search uses the codebooks described in the sections
pascal@12756	1415 above to find the best match of the perceptually weighted target, see
pascal@12756	1416 section 3.6.2. The search method is a multi-stage gain-shape
pascal@12756	1417 matching performed as follows. At each stage the best shape vector
pascal@12756	1418 is identified, then the gain is calculated and quantized, and finally
pascal@12756	1419 the target is updated in preparation for the next codebook search
pascal@12756	1420 stage. The number of stages is CB_NSTAGES=3.
pascal@12756	1421
pascal@12756	1422 If the target is the 23/22-sample vector the codebooks are indexed so
pascal@12756	1423 that the base codebook is followed by the expanded codebook. If the
pascal@12756	1424 target is 40 samples the order is as follows: base codebook,
pascal@12756	1425 augmented base codebook, expanded codebook, and augmented expanded
pascal@12756	1426 codebook. The size of each codebook section and its corresponding
pascal@12756	1427 augmented section is given by Table 3.1 in section 3.6.3.
pascal@12756	1428
pascal@12756	1429 For example, when the second 40-sample sub-block is coded, indices 0
pascal@12756	1430 - 107 correspond to the base codebook, 108 - 127 correspond to the
pascal@12756	1431 augmented base codebook, 128 - 235 correspond to the expanded
pascal@12756	1432 codebook, and indices 236 - 255 correspond to the augmented expanded
pascal@12756	1433 codebook. The indices are divided in the same fashion for all stages
pascal@12756	1434 in the example. Only in the case of coding the first 40-sample sub-
pascal@12756	1435 block is there a difference between stages (see Table 3.1).
pascal@12756	1436
pascal@12756	1437 3.6.4.1. Codebook Search at Each Stage
pascal@12756	1438
pascal@12756	1439 The codebooks are searched to find the best match to the target at
pascal@12756	1440 each stage. When the best match is found, the target is updated and
pascal@12756	1441 the next-stage search is started. The three chosen codebook vectors
pascal@12756	1442 and their corresponding gains constitute the encoded sub-block. The
pascal@12756	1443 best match is decided by the following three criteria:
pascal@12756	1444
pascal@12756	1445 1. Compute the measure
pascal@12756	1446
pascal@12756	1447 (target*cbvec)^2 / \|\|cbvec\|\|^2
pascal@12756	1448
pascal@12756	1449 for all codebook vectors, cbvec, and choose the codebook vector
pascal@12756	1450 maximizing the measure. The expression (target*cbvec) is the dot
pascal@12756	1451 product between the target vector to be coded and the codebook vector
pascal@12756	1452 for which we compute the measure. The norm, \|\|x\|\|, is defined as the
pascal@12756	1453 square root of (x*x).
pascal@12756	1454
pascal@12756	1455
pascal@12756	1456
pascal@12756	1457
pascal@12756	1458 Andersen, et al. Experimental [Page 26]
pascal@12756	1459
pascal@12756	1460 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1461
pascal@12756	1462
pascal@12756	1463 2. The absolute value of the gain, corresponding to the chosen
pascal@12756	1464 codebook vector, cbvec, must be smaller than a fixed limit,
pascal@12756	1465 CB_MAXGAIN=1.3:
pascal@12756	1466
pascal@12756	1467 \|gain\| < CB_MAXGAIN
pascal@12756	1468
pascal@12756	1469 where the gain is computed in the following way:
pascal@12756	1470
pascal@12756	1471 gain = (target*cbvec) / \|\|cbvec\|\|^2
pascal@12756	1472
pascal@12756	1473 3. For the first stage, the dot product of the chosen codebook vector
pascal@12756	1474 and target must be positive:
pascal@12756	1475
pascal@12756	1476 target*cbvec > 0
pascal@12756	1477
pascal@12756	1478 In practice the above criteria are used in a sequential search
pascal@12756	1479 through all codebook vectors. The best match is found by registering
pascal@12756	1480 a new max measure and index whenever the previously registered max
pascal@12756	1481 measure is surpassed and all other criteria are fulfilled. If none
pascal@12756	1482 of the codebook vectors fulfill (2) and (3), the first codebook
pascal@12756	1483 vector is selected.
pascal@12756	1484
pascal@12756	1485 3.6.4.2. Gain Quantization at Each Stage
pascal@12756	1486
pascal@12756	1487 The gain follows as a result of the computation
pascal@12756	1488
pascal@12756	1489 gain = (target*cbvec) / \|\|cbvec\|\|^2
pascal@12756	1490
pascal@12756	1491 for the optimal codebook vector found by the procedure in section
pascal@12756	1492 3.6.4.1.
pascal@12756	1493
pascal@12756	1494 The three stages quantize the gain, using 5, 4, and 3 bits,
pascal@12756	1495 respectively. In the first stage, the gain is limited to positive
pascal@12756	1496 values. This gain is quantized by finding the nearest value in the
pascal@12756	1497 quantization table gain_sq5Tbl.
pascal@12756	1498
pascal@12756	1499 gain_sq5Tbl[32]={0.037476, 0.075012, 0.112488, 0.150024, 0.187500,
pascal@12756	1500 0.224976, 0.262512, 0.299988, 0.337524, 0.375000,
pascal@12756	1501 0.412476, 0.450012, 0.487488, 0.525024, 0.562500,
pascal@12756	1502 0.599976, 0.637512, 0.674988, 0.712524, 0.750000,
pascal@12756	1503 0.787476, 0.825012, 0.862488, 0.900024, 0.937500,
pascal@12756	1504 0.974976, 1.012512, 1.049988, 1.087524, 1.125000,
pascal@12756	1505 1.162476, 1.200012}
pascal@12756	1506
pascal@12756	1507 The gains of the subsequent two stages can be either positive or
pascal@12756	1508 negative. The gains are quantized by using a quantization table
pascal@12756	1509 times a scale factor. The second stage uses the table gain_sq4Tbl,
pascal@12756	1510 and the third stage uses gain_sq3Tbl. The scale factor equates 0.1
pascal@12756	1511
pascal@12756	1512
pascal@12756	1513
pascal@12756	1514 Andersen, et al. Experimental [Page 27]
pascal@12756	1515
pascal@12756	1516 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1517
pascal@12756	1518
pascal@12756	1519 or the absolute value of the quantized gain representation value
pascal@12756	1520 obtained in the previous stage, whichever is larger. Again, the
pascal@12756	1521 resulting gain index is the index to the nearest value of the
pascal@12756	1522 quantization table times the scale factor.
pascal@12756	1523
pascal@12756	1524 gainQ = scaleFact * gain_sqXTbl[index]
pascal@12756	1525
pascal@12756	1526 gain_sq4Tbl[16]={-1.049988, -0.900024, -0.750000, -0.599976,
pascal@12756	1527 -0.450012, -0.299988, -0.150024, 0.000000, 0.150024,
pascal@12756	1528 0.299988, 0.450012, 0.599976, 0.750000, 0.900024,
pascal@12756	1529 1.049988, 1.200012}
pascal@12756	1530
pascal@12756	1531 gain_sq3Tbl[8]={-1.000000, -0.659973, -0.330017,0.000000,
pascal@12756	1532 0.250000, 0.500000, 0.750000, 1.00000}
pascal@12756	1533
pascal@12756	1534 3.6.4.3. Preparation of Target for Next Stage
pascal@12756	1535
pascal@12756	1536 Before performing the search for the next stage, the perceptually
pascal@12756	1537 weighted target vector is updated by subtracting from it the selected
pascal@12756	1538 codebook vector (from the perceptually weighted codebook) times the
pascal@12756	1539 corresponding quantized gain.
pascal@12756	1540
pascal@12756	1541 target[i] = target[i] - gainQ * selected_vec[i];
pascal@12756	1542
pascal@12756	1543 A reference implementation of the codebook encoding is found in
pascal@12756	1544 Appendix A.34.
pascal@12756	1545
pascal@12756	1546 3.7. Gain Correction Encoding
pascal@12756	1547
pascal@12756	1548 The start state is quantized in a relatively model independent manner
pascal@12756	1549 using 3 bits per sample. In contrast, the remaining parts of the
pascal@12756	1550 block are encoded by using an adaptive codebook. This codebook will
pascal@12756	1551 produce high matching accuracy whenever there is a high correlation
pascal@12756	1552 between the target and the best codebook vector. For unvoiced speech
pascal@12756	1553 segments and background noises, this is not necessarily so, which,
pascal@12756	1554 due to the nature of the squared error criterion, results in a coded
pascal@12756	1555 signal with less power than the target signal. As the coded start
pascal@12756	1556 state has good power matching to the target, the result is a power
pascal@12756	1557 fluctuation within the encoded frame. Perceptually, the main problem
pascal@12756	1558 with this is that the time envelope of the signal energy becomes
pascal@12756	1559 unsteady. To overcome this problem, the gains for the codebooks are
pascal@12756	1560 re-scaled after the codebook encoding by searching for a new gain
pascal@12756	1561 factor for the first stage codebook that provides better power
pascal@12756	1562 matching.
pascal@12756	1563
pascal@12756	1564 First, the energy for the target signal, tene, is computed along with
pascal@12756	1565 the energy for the coded signal, cene, given by the addition of the
pascal@12756	1566 three gain scaled codebook vectors. Because the gains of the second
pascal@12756	1567
pascal@12756	1568
pascal@12756	1569
pascal@12756	1570 Andersen, et al. Experimental [Page 28]
pascal@12756	1571
pascal@12756	1572 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1573
pascal@12756	1574
pascal@12756	1575 and third stage scale with the gain of the first stage, when the
pascal@12756	1576 first stage gain is changed from gain[0] to gain_sq5Tbl[i] the energy
pascal@12756	1577 of the coded signal changes from cene to
pascal@12756	1578
pascal@12756	1579 cene(gain_sq5Tbl[i]gain_sq5Tbl[i])/(gain[0]*gain[0])
pascal@12756	1580
pascal@12756	1581 where gain[0] is the gain for the first stage found in the original
pascal@12756	1582 codebook search. A refined search is performed by testing the gain
pascal@12756	1583 indices i=0 to 31, and as long as the new codebook energy as given
pascal@12756	1584 above is less than tene, the gain index for stage 1 is increased. A
pascal@12756	1585 restriction is applied so that the new gain value for stage 1 cannot
pascal@12756	1586 be more than two times higher than the original value found in the
pascal@12756	1587 codebook search. Note that by using this method we do not change the
pascal@12756	1588 shape of the encoded vector, only the gain or amplitude.
pascal@12756	1589
pascal@12756	1590 3.8. Bitstream Definition
pascal@12756	1591
pascal@12756	1592 The total number of bits used to describe one frame of 20 ms speech
pascal@12756	1593 is 304, which fits in 38 bytes and results in a bit rate of 15.20
pascal@12756	1594 kbit/s. For the case of a frame length of 30 ms speech, the total
pascal@12756	1595 number of bits used is 400, which fits in 50 bytes and results in a
pascal@12756	1596 bit rate of 13.33 kbit/s. In the bitstream definition, the bits are
pascal@12756	1597 distributed into three classes according to their bit error or loss
pascal@12756	1598 sensitivity. The most sensitive bits (class 1) are placed first in
pascal@12756	1599 the bitstream for each frame. The less sensitive bits (class 2) are
pascal@12756	1600 placed after the class 1 bits. The least sensitive bits (class 3)
pascal@12756	1601 are placed at the end of the bitstream for each frame.
pascal@12756	1602
pascal@12756	1603 In the 20/30 ms frame length cases for each class, the following hold
pascal@12756	1604 true: The class 1 bits occupy a total of 6/8 bytes (48/64 bits), the
pascal@12756	1605 class 2 bits occupy 8/12 bytes (64/96 bits), and the class 3 bits
pascal@12756	1606 occupy 24/30 bytes (191/239 bits). This distribution of the bits
pascal@12756	1607 enables the use of uneven level protection (ULP) as is exploited in
pascal@12756	1608 the payload format definition for iLBC [1]. The detailed bit
pascal@12756	1609 allocation is shown in the table below. When a quantization index is
pascal@12756	1610 distributed between more classes, the more significant bits belong to
pascal@12756	1611 the lowest class.
pascal@12756	1612
pascal@12756	1613
pascal@12756	1614
pascal@12756	1615
pascal@12756	1616
pascal@12756	1617
pascal@12756	1618
pascal@12756	1619
pascal@12756	1620
pascal@12756	1621
pascal@12756	1622
pascal@12756	1623
pascal@12756	1624
pascal@12756	1625
pascal@12756	1626 Andersen, et al. Experimental [Page 29]
pascal@12756	1627
pascal@12756	1628 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1629
pascal@12756	1630
pascal@12756	1631 Bitstream structure:
pascal@12756	1632
pascal@12756	1633 ------------------------------------------------------------------+
pascal@12756	1634 Parameter \| Bits Class <1,2,3> \|
pascal@12756	1635 \| 20 ms frame \| 30 ms frame \|
pascal@12756	1636 ----------------------------------+---------------+---------------+
pascal@12756	1637 Split 1 \| 6 <6,0,0> \| 6 <6,0,0> \|
pascal@12756	1638 LSF 1 Split 2 \| 7 <7,0,0> \| 7 <7,0,0> \|
pascal@12756	1639 LSF Split 3 \| 7 <7,0,0> \| 7 <7,0,0> \|
pascal@12756	1640 ------------------+---------------+---------------+
pascal@12756	1641 Split 1 \| NA (Not Appl.)\| 6 <6,0,0> \|
pascal@12756	1642 LSF 2 Split 2 \| NA \| 7 <7,0,0> \|
pascal@12756	1643 Split 3 \| NA \| 7 <7,0,0> \|
pascal@12756	1644 ------------------+---------------+---------------+
pascal@12756	1645 Sum \| 20 <20,0,0> \| 40 <40,0,0> \|
pascal@12756	1646 ----------------------------------+---------------+---------------+
pascal@12756	1647 Block Class \| 2 <2,0,0> \| 3 <3,0,0> \|
pascal@12756	1648 ----------------------------------+---------------+---------------+
pascal@12756	1649 Position 22 sample segment \| 1 <1,0,0> \| 1 <1,0,0> \|
pascal@12756	1650 ----------------------------------+---------------+---------------+
pascal@12756	1651 Scale Factor State Coder \| 6 <6,0,0> \| 6 <6,0,0> \|
pascal@12756	1652 ----------------------------------+---------------+---------------+
pascal@12756	1653 Sample 0 \| 3 <0,1,2> \| 3 <0,1,2> \|
pascal@12756	1654 Quantized Sample 1 \| 3 <0,1,2> \| 3 <0,1,2> \|
pascal@12756	1655 Residual : \| : : \| : : \|
pascal@12756	1656 State : \| : : \| : : \|
pascal@12756	1657 Samples : \| : : \| : : \|
pascal@12756	1658 Sample 56 \| 3 <0,1,2> \| 3 <0,1,2> \|
pascal@12756	1659 Sample 57 \| NA \| 3 <0,1,2> \|
pascal@12756	1660 ------------------+---------------+---------------+
pascal@12756	1661 Sum \| 171 <0,57,114>\| 174 <0,58,116>\|
pascal@12756	1662 ----------------------------------+---------------+---------------+
pascal@12756	1663 Stage 1 \| 7 <6,0,1> \| 7 <4,2,1> \|
pascal@12756	1664 CB for 22/23 Stage 2 \| 7 <0,0,7> \| 7 <0,0,7> \|
pascal@12756	1665 sample block Stage 3 \| 7 <0,0,7> \| 7 <0,0,7> \|
pascal@12756	1666 ------------------+---------------+---------------+
pascal@12756	1667 Sum \| 21 <6,0,15> \| 21 <4,2,15> \|
pascal@12756	1668 ----------------------------------+---------------+---------------+
pascal@12756	1669 Stage 1 \| 5 <2,0,3> \| 5 <1,1,3> \|
pascal@12756	1670 Gain for 22/23 Stage 2 \| 4 <1,1,2> \| 4 <1,1,2> \|
pascal@12756	1671 sample block Stage 3 \| 3 <0,0,3> \| 3 <0,0,3> \|
pascal@12756	1672 ------------------+---------------+---------------+
pascal@12756	1673 Sum \| 12 <3,1,8> \| 12 <2,2,8> \|
pascal@12756	1674 ----------------------------------+---------------+---------------+
pascal@12756	1675 Stage 1 \| 8 <7,0,1> \| 8 <6,1,1> \|
pascal@12756	1676 sub-block 1 Stage 2 \| 7 <0,0,7> \| 7 <0,0,7> \|
pascal@12756	1677 Stage 3 \| 7 <0,0,7> \| 7 <0,0,7> \|
pascal@12756	1678 ------------------+---------------+---------------+
pascal@12756	1679
pascal@12756	1680
pascal@12756	1681
pascal@12756	1682 Andersen, et al. Experimental [Page 30]
pascal@12756	1683
pascal@12756	1684 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1685
pascal@12756	1686
pascal@12756	1687 Stage 1 \| 8 <0,0,8> \| 8 <0,7,1> \|
pascal@12756	1688 sub-block 2 Stage 2 \| 8 <0,0,8> \| 8 <0,0,8> \|
pascal@12756	1689 Indices Stage 3 \| 8 <0,0,8> \| 8 <0,0,8> \|
pascal@12756	1690 for CB ------------------+---------------+---------------+
pascal@12756	1691 sub-blocks Stage 1 \| NA \| 8 <0,7,1> \|
pascal@12756	1692 sub-block 3 Stage 2 \| NA \| 8 <0,0,8> \|
pascal@12756	1693 Stage 3 \| NA \| 8 <0,0,8> \|
pascal@12756	1694 ------------------+---------------+---------------+
pascal@12756	1695 Stage 1 \| NA \| 8 <0,7,1> \|
pascal@12756	1696 sub-block 4 Stage 2 \| NA \| 8 <0,0,8> \|
pascal@12756	1697 Stage 3 \| NA \| 8 <0,0,8> \|
pascal@12756	1698 ------------------+---------------+---------------+
pascal@12756	1699 Sum \| 46 <7,0,39> \| 94 <6,22,66> \|
pascal@12756	1700 ----------------------------------+---------------+---------------+
pascal@12756	1701 Stage 1 \| 5 <1,2,2> \| 5 <1,2,2> \|
pascal@12756	1702 sub-block 1 Stage 2 \| 4 <1,1,2> \| 4 <1,2,1> \|
pascal@12756	1703 Stage 3 \| 3 <0,0,3> \| 3 <0,0,3> \|
pascal@12756	1704 ------------------+---------------+---------------+
pascal@12756	1705 Stage 1 \| 5 <1,1,3> \| 5 <0,2,3> \|
pascal@12756	1706 sub-block 2 Stage 2 \| 4 <0,2,2> \| 4 <0,2,2> \|
pascal@12756	1707 Stage 3 \| 3 <0,0,3> \| 3 <0,0,3> \|
pascal@12756	1708 Gains for ------------------+---------------+---------------+
pascal@12756	1709 sub-blocks Stage 1 \| NA \| 5 <0,1,4> \|
pascal@12756	1710 sub-block 3 Stage 2 \| NA \| 4 <0,1,3> \|
pascal@12756	1711 Stage 3 \| NA \| 3 <0,0,3> \|
pascal@12756	1712 ------------------+---------------+---------------+
pascal@12756	1713 Stage 1 \| NA \| 5 <0,1,4> \|
pascal@12756	1714 sub-block 4 Stage 2 \| NA \| 4 <0,1,3> \|
pascal@12756	1715 Stage 3 \| NA \| 3 <0,0,3> \|
pascal@12756	1716 ------------------+---------------+---------------+
pascal@12756	1717 Sum \| 24 <3,6,15> \| 48 <2,12,34> \|
pascal@12756	1718 ----------------------------------+---------------+---------------+
pascal@12756	1719 Empty frame indicator \| 1 <0,0,1> \| 1 <0,0,1> \|
pascal@12756	1720 -------------------------------------------------------------------
pascal@12756	1721 SUM 304 <48,64,192> 400 <64,96,240>
pascal@12756	1722
pascal@12756	1723 Table 3.2. The bitstream definition for iLBC for both the 20 ms
pascal@12756	1724 frame size mode and the 30 ms frame size mode.
pascal@12756	1725
pascal@12756	1726 When packetized into the payload, the bits MUST be sorted as follows:
pascal@12756	1727 All the class 1 bits in the order (from top to bottom) as specified
pascal@12756	1728 in the table, all the class 2 bits (from top to bottom), and all the
pascal@12756	1729 class 3 bits in the same sequential order. The last bit, the empty
pascal@12756	1730 frame indicator, SHOULD be set to zero by the encoder. If this bit
pascal@12756	1731 is set to 1 the decoder SHOULD treat the data as a lost frame. For
pascal@12756	1732 example, this bit can be set to 1 to indicate lost frame for file
pascal@12756	1733 storage format, as in [1].
pascal@12756	1734
pascal@12756	1735
pascal@12756	1736
pascal@12756	1737
pascal@12756	1738 Andersen, et al. Experimental [Page 31]
pascal@12756	1739
pascal@12756	1740 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1741
pascal@12756	1742
pascal@12756	1743 4. Decoder Principles
pascal@12756	1744
pascal@12756	1745 This section describes the principles of each component of the
pascal@12756	1746 decoder algorithm.
pascal@12756	1747
pascal@12756	1748 +-------------+ +--------+ +---------------+
pascal@12756	1749 payload -> \| 1. Get para \| -> \| 2. LPC \| -> \| 3. Sc Dequant \| ->
pascal@12756	1750 +-------------+ +--------+ +---------------+
pascal@12756	1751
pascal@12756	1752 +-------------+ +------------------+
pascal@12756	1753 -> \| 4. Mem setup\| -> \| 5. Construct res \|------->
pascal@12756	1754 \| +-------------+ +------------------- \|
pascal@12756	1755 ---------<-----------<-----------<------------
pascal@12756	1756 Sub-frame 0...2/4 (20 ms/30 ms)
pascal@12756	1757
pascal@12756	1758 +----------------+ +----------+
pascal@12756	1759 -> \| 6. Enhance res \| -> \| 7. Synth \| ------------>
pascal@12756	1760 +----------------+ +----------+
pascal@12756	1761
pascal@12756	1762 +-----------------+
pascal@12756	1763 -> \| 8. Post Process \| ----------------> decoded speech
pascal@12756	1764 +-----------------+
pascal@12756	1765
pascal@12756	1766 Figure 4.1. Flow chart of the iLBC decoder. If a frame was lost,
pascal@12756	1767 steps 1 to 5 SHOULD be replaced by a PLC algorithm.
pascal@12756	1768
pascal@12756	1769 1. Extract the parameters from the bitstream.
pascal@12756	1770
pascal@12756	1771 2. Decode the LPC and interpolate (section 4.1).
pascal@12756	1772
pascal@12756	1773 3. Construct the 57/58-sample start state (section 4.2).
pascal@12756	1774
pascal@12756	1775 4. Set up the memory by using data from the decoded residual. This
pascal@12756	1776 memory is used for codebook construction. For blocks preceding
pascal@12756	1777 the start state, both the decoded residual and the target are time
pascal@12756	1778 reversed. Sub-frames are decoded in the same order as they were
pascal@12756	1779 encoded.
pascal@12756	1780
pascal@12756	1781 5. Construct the residuals of this sub-frame (gain[0]*cbvec[0] +
pascal@12756	1782 gain[1]cbvec[1] + gain[2]cbvec[2]). Repeat 4 and 5 until the
pascal@12756	1783 residual of all sub-blocks has been constructed.
pascal@12756	1784
pascal@12756	1785 6. Enhance the residual with the post filter (section 4.6).
pascal@12756	1786
pascal@12756	1787 7. Synthesis of the residual (section 4.7).
pascal@12756	1788
pascal@12756	1789 8. Post process with HP filter, if desired (section 4.8).
pascal@12756	1790
pascal@12756	1791
pascal@12756	1792
pascal@12756	1793
pascal@12756	1794 Andersen, et al. Experimental [Page 32]
pascal@12756	1795
pascal@12756	1796 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1797
pascal@12756	1798
pascal@12756	1799 4.1. LPC Filter Reconstruction
pascal@12756	1800
pascal@12756	1801 The decoding of the LP filter parameters is very straightforward.
pascal@12756	1802 For a set of three/six indices, the corresponding LSF vector(s) are
pascal@12756	1803 found by simple table lookup. For each of the LSF vectors, the three
pascal@12756	1804 split vectors are concatenated to obtain qlsf1 and qlsf2,
pascal@12756	1805 respectively (in the 20 ms mode only one LSF vector, qlsf, is
pascal@12756	1806 constructed). The next step is the stability check described in
pascal@12756	1807 section 3.2.5 followed by the interpolation scheme described in
pascal@12756	1808 section 3.2.6 (3.2.7 for 20 ms frames). The only difference is that
pascal@12756	1809 only the quantized LSFs are known at the decoder, and hence the
pascal@12756	1810 unquantized LSFs are not processed.
pascal@12756	1811
pascal@12756	1812 A reference implementation of the LPC filter reconstruction is given
pascal@12756	1813 in Appendix A.36.
pascal@12756	1814
pascal@12756	1815 4.2. Start State Reconstruction
pascal@12756	1816
pascal@12756	1817 The scalar encoded STATE_SHORT_LEN=58 (STATE_SHORT_LEN=57 in the 20
pascal@12756	1818 ms mode) state samples are reconstructed by 1) forming a set of
pascal@12756	1819 samples (by table lookup) from the index stream idxVec[n], 2)
pascal@12756	1820 multiplying the set with 1/scal=(10^qmax)/4.5, 3) time reversing the
pascal@12756	1821 57/58 samples, 4) filtering the time reversed block with the
pascal@12756	1822 dispersion (all-pass) filter used in the encoder (as described in
pascal@12756	1823 section 3.5.2); this compensates for the phase distortion of the
pascal@12756	1824 earlier filter operation, and 5 reversing the 57/58 samples from the
pascal@12756	1825 previous step.
pascal@12756	1826
pascal@12756	1827 in(0..(STATE_SHORT_LEN-1)) = time reversed samples from table
pascal@12756	1828 look-up,
pascal@12756	1829 idxVecDec((STATE_SHORT_LEN-1)..0)
pascal@12756	1830
pascal@12756	1831 in(STATE_SHORT_LEN..(2*STATE_SHORT_LEN-1)) = 0
pascal@12756	1832
pascal@12756	1833 Pk(z) = A~rk(z)/A~k(z), where
pascal@12756	1834 ___
pascal@12756	1835 \
pascal@12756	1836 A~rk(z)= z^(-LPC_FILTERORDER) + > a~ki*z^(i-(LPC_FILTERORDER-1))
pascal@12756	1837 /__
pascal@12756	1838 i=0...(LPC_FILTERORDER-1)
pascal@12756	1839
pascal@12756	1840 and A~k(z) is taken from the block where the start state begins
pascal@12756	1841
pascal@12756	1842 in -> Pk(z) -> filtered
pascal@12756	1843
pascal@12756	1844 out(k) = filtered(STATE_SHORT_LEN-1-k) +
pascal@12756	1845 filtered(2*STATE_SHORT_LEN-1-k),
pascal@12756	1846 k=0..(STATE_SHORT_LEN-1)
pascal@12756	1847
pascal@12756	1848
pascal@12756	1849
pascal@12756	1850 Andersen, et al. Experimental [Page 33]
pascal@12756	1851
pascal@12756	1852 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1853
pascal@12756	1854
pascal@12756	1855 The remaining 23/22 samples in the state are reconstructed by the
pascal@12756	1856 same adaptive codebook technique described in section 4.3. The
pascal@12756	1857 location bit determines whether these are the first or the last 23/22
pascal@12756	1858 samples of the 80-sample state vector. If the remaining 23/22
pascal@12756	1859 samples are the first samples, then the scalar encoded
pascal@12756	1860 STATE_SHORT_LEN state samples are time-reversed before initialization
pascal@12756	1861 of the adaptive codebook memory vector.
pascal@12756	1862
pascal@12756	1863 A reference implementation of the start state reconstruction is given
pascal@12756	1864 in Appendix A.44.
pascal@12756	1865
pascal@12756	1866 4.3. Excitation Decoding Loop
pascal@12756	1867
pascal@12756	1868 The decoding of the LPC excitation vector proceeds in the same order
pascal@12756	1869 in which the residual was encoded at the encoder. That is, after the
pascal@12756	1870 decoding of the entire 80-sample state vector, the forward sub-blocks
pascal@12756	1871 (corresponding to samples occurring after the state vector samples)
pascal@12756	1872 are decoded, and then the backward sub-blocks (corresponding to
pascal@12756	1873 samples occurring before the state vector) are decoded, resulting in
pascal@12756	1874 a fully decoded block of excitation signal samples.
pascal@12756	1875
pascal@12756	1876 In particular, each sub-block is decoded by using the multistage
pascal@12756	1877 adaptive codebook decoding module described in section 4.4. This
pascal@12756	1878 module relies upon an adaptive codebook memory constructed before
pascal@12756	1879 each run of the adaptive codebook decoding. The construction of the
pascal@12756	1880 adaptive codebook memory in the decoder is identical to the method
pascal@12756	1881 outlined in section 3.6.3, except that it is done on the codebook
pascal@12756	1882 memory without perceptual weighting.
pascal@12756	1883
pascal@12756	1884 For the initial forward sub-block, the last STATE_LEN=80 samples of
pascal@12756	1885 the length CB_LMEM=147 adaptive codebook memory are filled with the
pascal@12756	1886 samples of the state vector. For subsequent forward sub-blocks, the
pascal@12756	1887 first SUBL=40 samples of the adaptive codebook memory are discarded,
pascal@12756	1888 the remaining samples are shifted by SUBL samples toward the
pascal@12756	1889 beginning of the vector, and the newly decoded SUBL=40 samples are
pascal@12756	1890 placed at the end of the adaptive codebook memory. For backward
pascal@12756	1891 sub-blocks, the construction is similar, except that every vector of
pascal@12756	1892 samples involved is first time reversed.
pascal@12756	1893
pascal@12756	1894 A reference implementation of the excitation decoding loop is found
pascal@12756	1895 in Appendix A.5.
pascal@12756	1896
pascal@12756	1897
pascal@12756	1898
pascal@12756	1899
pascal@12756	1900
pascal@12756	1901
pascal@12756	1902
pascal@12756	1903
pascal@12756	1904
pascal@12756	1905
pascal@12756	1906 Andersen, et al. Experimental [Page 34]
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pascal@12756	1908 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1909
pascal@12756	1910
pascal@12756	1911 4.4. Multistage Adaptive Codebook Decoding
pascal@12756	1912
pascal@12756	1913 The Multistage Adaptive Codebook Decoding module is used at both the
pascal@12756	1914 sender (encoder) and the receiver (decoder) ends to produce a
pascal@12756	1915 synthetic signal in the residual domain that is eventually used to
pascal@12756	1916 produce synthetic speech. The module takes the index values used to
pascal@12756	1917 construct vectors that are scaled and summed together to produce a
pascal@12756	1918 synthetic signal that is the output of the module.
pascal@12756	1919
pascal@12756	1920 4.4.1. Construction of the Decoded Excitation Signal
pascal@12756	1921
pascal@12756	1922 The unpacked index values provided at the input to the module are
pascal@12756	1923 references to extended codebooks, which are constructed as described
pascal@12756	1924 in section 3.6.3, except that they are based on the codebook memory
pascal@12756	1925 without the perceptual weighting. The unpacked three indices are
pascal@12756	1926 used to look up three codebook vectors. The unpacked three gain
pascal@12756	1927 indices are used to decode the corresponding 3 gains. In this
pascal@12756	1928 decoding, the successive rescaling, as described in section 3.6.4.2,
pascal@12756	1929 is applied.
pascal@12756	1930
pascal@12756	1931 A reference implementation of the adaptive codebook decoding is
pascal@12756	1932 listed in Appendix A.32.
pascal@12756	1933
pascal@12756	1934 4.5. Packet Loss Concealment
pascal@12756	1935
pascal@12756	1936 If packet loss occurs, the decoder receives a signal saying that
pascal@12756	1937 information regarding a block is lost. For such blocks it is
pascal@12756	1938 RECOMMENDED to use a Packet Loss Concealment (PLC) unit to create a
pascal@12756	1939 decoded signal that masks the effect of that packet loss. In the
pascal@12756	1940 following we will describe an example of a PLC unit that can be used
pascal@12756	1941 with the iLBC codec. As the PLC unit is used only at the decoder,
pascal@12756	1942 the PLC unit does not affect interoperability between
pascal@12756	1943 implementations. Other PLC implementations MAY therefore be used.
pascal@12756	1944
pascal@12756	1945 The PLC described operates on the LP filters and the excitation
pascal@12756	1946 signals and is based on the following principles:
pascal@12756	1947
pascal@12756	1948 4.5.1. Block Received Correctly and Previous Block Also Received
pascal@12756	1949
pascal@12756	1950 If the block is received correctly, the PLC only records state
pascal@12756	1951 information of the current block that can be used in case the next
pascal@12756	1952 block is lost. The LP filter coefficients for each sub-block and the
pascal@12756	1953 entire decoded excitation signal are all saved in the decoder state
pascal@12756	1954 structure. All of this information will be needed if the following
pascal@12756	1955 block is lost.
pascal@12756	1956
pascal@12756	1957
pascal@12756	1958
pascal@12756	1959
pascal@12756	1960
pascal@12756	1961
pascal@12756	1962 Andersen, et al. Experimental [Page 35]
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pascal@12756	1964 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	1965
pascal@12756	1966
pascal@12756	1967 4.5.2. Block Not Received
pascal@12756	1968
pascal@12756	1969 If the block is not received, the block substitution is based on a
pascal@12756	1970 pitch-synchronous repetition of the excitation signal, which is
pascal@12756	1971 filtered by the last LP filter of the previous block. The previous
pascal@12756	1972 block's information is stored in the decoder state structure.
pascal@12756	1973
pascal@12756	1974 A correlation analysis is performed on the previous block's
pascal@12756	1975 excitation signal in order to detect the amount of pitch periodicity
pascal@12756	1976 and a pitch value. The correlation measure is also used to decide on
pascal@12756	1977 the voicing level (the degree to which the previous block's
pascal@12756	1978 excitation was a voiced or roughly periodic signal). The excitation
pascal@12756	1979 in the previous block is used to create an excitation for the block
pascal@12756	1980 to be substituted, such that the pitch of the previous block is
pascal@12756	1981 maintained. Therefore, the new excitation is constructed in a
pascal@12756	1982 pitch-synchronous manner. In order to avoid a buzzy-sounding
pascal@12756	1983 substituted block, a random excitation is mixed with the new pitch
pascal@12756	1984 periodic excitation, and the relative use of the two components is
pascal@12756	1985 computed from the correlation measure (voicing level).
pascal@12756	1986
pascal@12756	1987 For the block to be substituted, the newly constructed excitation
pascal@12756	1988 signal is then passed through the LP filter to produce the speech
pascal@12756	1989 that will be substituted for the lost block.
pascal@12756	1990
pascal@12756	1991 For several consecutive lost blocks, the packet loss concealment
pascal@12756	1992 continues in a similar manner. The correlation measure of the last
pascal@12756	1993 block received is still used along with the same pitch value. The LP
pascal@12756	1994 filters of the last block received are also used again. The energy
pascal@12756	1995 of the substituted excitation for consecutive lost blocks is
pascal@12756	1996 decreased, leading to a dampened excitation, and therefore to
pascal@12756	1997 dampened speech.
pascal@12756	1998
pascal@12756	1999 4.5.3. Block Received Correctly When Previous Block Not Received
pascal@12756	2000
pascal@12756	2001 For the case in which a block is received correctly when the previous
pascal@12756	2002 block was not, the correctly received block's directly decoded speech
pascal@12756	2003 (based solely on the received block) is not used as the actual
pascal@12756	2004 output. The reason for this is that the directly decoded speech does
pascal@12756	2005 not necessarily smoothly merge into the synthetic speech generated
pascal@12756	2006 for the previous lost block. If the two signals are not smoothly
pascal@12756	2007 merged, an audible discontinuity is accidentally produced.
pascal@12756	2008 Therefore, a correlation analysis between the two blocks of
pascal@12756	2009 excitation signal (the excitation of the previous concealed block and
pascal@12756	2010 that of the current received block) is performed to find the best
pascal@12756	2011 phase match. Then a simple overlap-add procedure is performed to
pascal@12756	2012 merge the previous excitation smoothly into the current block's
pascal@12756	2013 excitation.
pascal@12756	2014
pascal@12756	2015
pascal@12756	2016
pascal@12756	2017
pascal@12756	2018 Andersen, et al. Experimental [Page 36]
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pascal@12756	2020 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2021
pascal@12756	2022
pascal@12756	2023 The exact implementation of the packet loss concealment does not
pascal@12756	2024 influence interoperability of the codec.
pascal@12756	2025
pascal@12756	2026 A reference implementation of the packet loss concealment is
pascal@12756	2027 suggested in Appendix A.14. Exact compliance with this suggested
pascal@12756	2028 algorithm is not needed for a reference implementation to be fully
pascal@12756	2029 compatible with the overall codec specification.
pascal@12756	2030
pascal@12756	2031 4.6. Enhancement
pascal@12756	2032
pascal@12756	2033 The decoder contains an enhancement unit that operates on the
pascal@12756	2034 reconstructed excitation signal. The enhancement unit increases the
pascal@12756	2035 perceptual quality of the reconstructed signal by reducing the
pascal@12756	2036 speech-correlated noise in the voiced speech segments. Compared to
pascal@12756	2037 traditional postfilters, the enhancer has an advantage in that it can
pascal@12756	2038 only modify the excitation signal slightly. This means that there is
pascal@12756	2039 no risk of over enhancement. The enhancer works very similarly for
pascal@12756	2040 both the 20 ms frame size mode and the 30 ms frame size mode.
pascal@12756	2041
pascal@12756	2042 For the mode with 20 ms frame size, the enhancer uses a memory of six
pascal@12756	2043 80-sample excitation blocks prior in time plus the two new 80-sample
pascal@12756	2044 excitation blocks. For each block of 160 new unenhanced excitation
pascal@12756	2045 samples, 160 enhanced excitation samples are produced. The enhanced
pascal@12756	2046 excitation is 40-sample delayed compared to the unenhanced
pascal@12756	2047 excitation, as the enhancer algorithm uses lookahead.
pascal@12756	2048
pascal@12756	2049 For the mode with 30 ms frame size, the enhancer uses a memory of
pascal@12756	2050 five 80-sample excitation blocks prior in time plus the three new
pascal@12756	2051 80-sample excitation blocks. For each block of 240 new unenhanced
pascal@12756	2052 excitation samples, 240 enhanced excitation samples are produced.
pascal@12756	2053 The enhanced excitation is 80-sample delayed compared to the
pascal@12756	2054 unenhanced excitation, as the enhancer algorithm uses lookahead.
pascal@12756	2055
pascal@12756	2056 Outline of Enhancer
pascal@12756	2057
pascal@12756	2058 The speech enhancement unit operates on sub-blocks of 80 samples,
pascal@12756	2059 which means that there are two/three 80 sample sub-blocks per frame.
pascal@12756	2060 Each of these two/three sub-blocks is enhanced separately, but in an
pascal@12756	2061 analogous manner.
pascal@12756	2062
pascal@12756	2063
pascal@12756	2064
pascal@12756	2065
pascal@12756	2066
pascal@12756	2067
pascal@12756	2068
pascal@12756	2069
pascal@12756	2070
pascal@12756	2071
pascal@12756	2072
pascal@12756	2073
pascal@12756	2074 Andersen, et al. Experimental [Page 37]
pascal@12756	2075
pascal@12756	2076 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2077
pascal@12756	2078
pascal@12756	2079 unenhanced residual
pascal@12756	2080 \|
pascal@12756	2081 \| +---------------+ +--------------+
pascal@12756	2082 +-> \| 1. Pitch Est \| -> \| 2. Find PSSQ \| -------->
pascal@12756	2083 +---------------+ \| +--------------+
pascal@12756	2084 +-----<-------<------<--+
pascal@12756	2085 +------------+ enh block 0..1/2 \|
pascal@12756	2086 -> \| 3. Smooth \| \|
pascal@12756	2087 +------------+ \|
pascal@12756	2088 \ \|
pascal@12756	2089 /\ \|
pascal@12756	2090 / \ Already \|
pascal@12756	2091 / 4. \----------->----------->-----------+ \|
pascal@12756	2092 \Crit/ Fulfilled \| \|
pascal@12756	2093 \? / v \|
pascal@12756	2094 \/ \| \|
pascal@12756	2095 \ +-----------------+ +---------+ \| \|
pascal@12756	2096 Not +->\| 5. Use Constr. \| -> \| 6. Mix \| ----->
pascal@12756	2097 Fulfilled +-----------------+ +---------+
pascal@12756	2098
pascal@12756	2099 ---------------> enhanced residual
pascal@12756	2100
pascal@12756	2101 Figure 4.2. Flow chart of the enhancer.
pascal@12756	2102
pascal@12756	2103 1. Pitch estimation of each of the two/three new 80-sample blocks.
pascal@12756	2104
pascal@12756	2105 2. Find the pitch-period-synchronous sequence n (for block k) by a
pascal@12756	2106 search around the estimated pitch value. Do this for n=1,2,3,
pascal@12756	2107 -1,-2,-3.
pascal@12756	2108
pascal@12756	2109 3. Calculate the smoothed residual generated by the six pitch-
pascal@12756	2110 period-synchronous sequences from prior step.
pascal@12756	2111
pascal@12756	2112 4. Check if the smoothed residual satisfies the criterion (section
pascal@12756	2113 4.6.4).
pascal@12756	2114
pascal@12756	2115 5. Use constraint to calculate mixing factor (section 4.6.5).
pascal@12756	2116
pascal@12756	2117 6. Mix smoothed signal with unenhanced residual (pssq(n) n=0).
pascal@12756	2118
pascal@12756	2119 The main idea of the enhancer is to find three 80 sample blocks
pascal@12756	2120 before and three 80-sample blocks after the analyzed unenhanced sub-
pascal@12756	2121 block and to use these to improve the quality of the excitation in
pascal@12756	2122 that sub-block. The six blocks are chosen so that they have the
pascal@12756	2123 highest possible correlation with the unenhanced sub-block that is
pascal@12756	2124 being enhanced. In other words, the six blocks are pitch-period-
pascal@12756	2125 synchronous sequences to the unenhanced sub-block.
pascal@12756	2126
pascal@12756	2127
pascal@12756	2128
pascal@12756	2129
pascal@12756	2130 Andersen, et al. Experimental [Page 38]
pascal@12756	2131
pascal@12756	2132 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2133
pascal@12756	2134
pascal@12756	2135 A linear combination of the six pitch-period-synchronous sequences is
pascal@12756	2136 calculated that approximates the sub-block. If the squared error
pascal@12756	2137 between the approximation and the unenhanced sub-block is small
pascal@12756	2138 enough, the enhanced residual is set equal to this approximation.
pascal@12756	2139 For the cases when the squared error criterion is not fulfilled, a
pascal@12756	2140 linear combination of the approximation and the unenhanced residual
pascal@12756	2141 forms the enhanced residual.
pascal@12756	2142
pascal@12756	2143 4.6.1. Estimating the Pitch
pascal@12756	2144
pascal@12756	2145 Pitch estimates are needed to determine the locations of the pitch-
pascal@12756	2146 period-synchronous sequences in a complexity-efficient way. For each
pascal@12756	2147 of the new two/three sub-blocks, a pitch estimate is calculated by
pascal@12756	2148 finding the maximum correlation in the range from lag 20 to lag 120.
pascal@12756	2149 These pitch estimates are used to narrow down the search for the best
pascal@12756	2150 possible pitch-period-synchronous sequences.
pascal@12756	2151
pascal@12756	2152 4.6.2. Determination of the Pitch-Synchronous Sequences
pascal@12756	2153
pascal@12756	2154 Upon receiving the pitch estimates from the prior step, the enhancer
pascal@12756	2155 analyzes and enhances one 80-sample sub-block at a time. The pitch-
pascal@12756	2156 period-synchronous-sequences pssq(n) can be viewed as vectors of
pascal@12756	2157 length 80 samples each shifted n*lag samples from the current sub-
pascal@12756	2158 block. The six pitch-period-synchronous-sequences, pssq(-3) to
pascal@12756	2159 pssq(-1) and pssq(1) to pssq(3), are found one at a time by the steps
pascal@12756	2160 below:
pascal@12756	2161
pascal@12756	2162 1) Calculate the estimate of the position of the pssq(n). For
pascal@12756	2163 pssq(n) in front of pssq(0) (n > 0), the location of the pssq(n)
pascal@12756	2164 is estimated by moving one pitch estimate forward in time from the
pascal@12756	2165 exact location of pssq(n-1). Similarly, pssq(n) behind pssq(0) (n
pascal@12756	2166 < 0) is estimated by moving one pitch estimate backward in time
pascal@12756	2167 from the exact location of pssq(n+1). If the estimated pssq(n)
pascal@12756	2168 vector location is totally within the enhancer memory (Figure
pascal@12756	2169 4.3), steps 2, 3, and 4 are performed, otherwise the pssq(n) is
pascal@12756	2170 set to zeros.
pascal@12756	2171
pascal@12756	2172 2) Compute the correlation between the unenhanced excitation and
pascal@12756	2173 vectors around the estimated location interval of pssq(n). The
pascal@12756	2174 correlation is calculated in the interval estimated location +/- 2
pascal@12756	2175 samples. This results in five correlation values.
pascal@12756	2176
pascal@12756	2177 3) The five correlation values are upsampled by a factor of 4, by
pascal@12756	2178 using four simple upsampling filters (MA filters with coefficients
pascal@12756	2179 upsFilter1.. upsFilter4). Within these the maximum value is
pascal@12756	2180 found, which specifies the best pitch-period with a resolution of
pascal@12756	2181 a quarter of a sample.
pascal@12756	2182
pascal@12756	2183
pascal@12756	2184
pascal@12756	2185
pascal@12756	2186 Andersen, et al. Experimental [Page 39]
pascal@12756	2187
pascal@12756	2188 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2189
pascal@12756	2190
pascal@12756	2191 upsFilter1[7]={0.000000 0.000000 0.000000 1.000000
pascal@12756	2192 0.000000 0.000000 0.000000}
pascal@12756	2193 upsFilter2[7]={0.015625 -0.076904 0.288330 0.862061
pascal@12756	2194 -0.106445 0.018799 -0.015625}
pascal@12756	2195 upsFilter3[7]={0.023682 -0.124268 0.601563 0.601563
pascal@12756	2196 -0.124268 0.023682 -0.023682}
pascal@12756	2197 upsFilter4[7]={0.018799 -0.106445 0.862061 0.288330
pascal@12756	2198 -0.076904 0.015625 -0.018799}
pascal@12756	2199
pascal@12756	2200 4) Generate the pssq(n) vector by upsampling of the excitation memory
pascal@12756	2201 and extracting the sequence that corresponds to the lag delay that
pascal@12756	2202 was calculated in prior step.
pascal@12756	2203
pascal@12756	2204 With the steps above, all the pssq(n) can be found in an iterative
pascal@12756	2205 manner, first moving backward in time from pssq(0) and then forward
pascal@12756	2206 in time from pssq(0).
pascal@12756	2207
pascal@12756	2208
pascal@12756	2209 0 159 319 479 639
pascal@12756	2210 +---------------------------------------------------------------+
pascal@12756	2211 \| -5 \| -4 \| -3 \| -2 \| -1 \| 0 \| 1 \| 2 \|
pascal@12756	2212 +---------------------------------------------------------------+
pascal@12756	2213 \|pssq 0 \|
pascal@12756	2214 \|pssq -1\| \|pssq 1 \|
pascal@12756	2215 \|pssq -2\| \|pssq 2 \|
pascal@12756	2216 \|pssq -3\| \|pssq 3 \|
pascal@12756	2217
pascal@12756	2218 Figure 4.3. Enhancement for 20 ms frame size.
pascal@12756	2219
pascal@12756	2220 Figure 4.3 depicts pitch-period-synchronous sequences in the
pascal@12756	2221 enhancement of the first 80 sample block in the 20 ms frame size
pascal@12756	2222 mode. The unenhanced signal input is stored in the last two sub-
pascal@12756	2223 blocks (1 - 2), and the six other sub-blocks contain unenhanced
pascal@12756	2224 residual prior-in-time. We perform the enhancement algorithm on two
pascal@12756	2225 blocks of 80 samples, where the first of the two blocks consists of
pascal@12756	2226 the last 40 samples of sub-block 0 and the first 40 samples of sub-
pascal@12756	2227 block 1. The second 80-sample block consists of the last 40 samples
pascal@12756	2228 of sub-block 1 and the first 40 samples of sub-block 2.
pascal@12756	2229
pascal@12756	2230
pascal@12756	2231
pascal@12756	2232
pascal@12756	2233
pascal@12756	2234
pascal@12756	2235
pascal@12756	2236
pascal@12756	2237
pascal@12756	2238
pascal@12756	2239
pascal@12756	2240
pascal@12756	2241
pascal@12756	2242 Andersen, et al. Experimental [Page 40]
pascal@12756	2243
pascal@12756	2244 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2245
pascal@12756	2246
pascal@12756	2247 0 159 319 479 639
pascal@12756	2248 +---------------------------------------------------------------+
pascal@12756	2249 \| -4 \| -3 \| -2 \| -1 \| 0 \| 1 \| 2 \| 3 \|
pascal@12756	2250 +---------------------------------------------------------------+
pascal@12756	2251 \|pssq 0 \|
pascal@12756	2252 \|pssq -1\| \|pssq 1 \|
pascal@12756	2253 \|pssq -2\| \|pssq 2 \|
pascal@12756	2254 \|pssq -3\| \|pssq 3 \|
pascal@12756	2255
pascal@12756	2256 Figure 4.4. Enhancement for 30 ms frame size.
pascal@12756	2257
pascal@12756	2258 Figure 4.4 depicts pitch-period-synchronous sequences in the
pascal@12756	2259 enhancement of the first 80-sample block in the 30 ms frame size
pascal@12756	2260 mode. The unenhanced signal input is stored in the last three sub-
pascal@12756	2261 blocks (1 - 3). The five other sub-blocks contain unenhanced
pascal@12756	2262 residual prior-in-time. The enhancement algorithm is performed on
pascal@12756	2263 the three 80 sample sub-blocks 0, 1, and 2.
pascal@12756	2264
pascal@12756	2265 4.6.3. Calculation of the Smoothed Excitation
pascal@12756	2266
pascal@12756	2267 A linear combination of the six pssq(n) (n!=0) form a smoothed
pascal@12756	2268 approximation, z, of pssq(0). Most of the weight is put on the
pascal@12756	2269 sequences that are close to pssq(0), as these are likely to be most
pascal@12756	2270 similar to pssq(0). The smoothed vector is also rescaled so that the
pascal@12756	2271 energy of z is the same as the energy of pssq(0).
pascal@12756	2272
pascal@12756	2273 ___
pascal@12756	2274 \
pascal@12756	2275 y = > pssq(i) * pssq_weight(i)
pascal@12756	2276 /__
pascal@12756	2277 i=-3,-2,-1,1,2,3
pascal@12756	2278
pascal@12756	2279 pssq_weight(i) = 0.5(1-cos(2pi(i+4)/(23+2)))
pascal@12756	2280
pascal@12756	2281 z = C * y, where C = \|\|pssq(0)\|\|/\|\|y\|\|
pascal@12756	2282
pascal@12756	2283 4.6.4. Enhancer Criterion
pascal@12756	2284
pascal@12756	2285 The criterion of the enhancer is that the enhanced excitation is not
pascal@12756	2286 allowed to differ much from the unenhanced excitation. This
pascal@12756	2287 criterion is checked for each 80-sample sub-block.
pascal@12756	2288
pascal@12756	2289 e < (b * \|\|pssq(0)\|\|^2), where b=0.05 and (Constraint 1)
pascal@12756	2290
pascal@12756	2291 e = (pssq(0)-z)(pssq(0)-z), and "" means the dot product
pascal@12756	2292
pascal@12756	2293
pascal@12756	2294
pascal@12756	2295
pascal@12756	2296
pascal@12756	2297
pascal@12756	2298 Andersen, et al. Experimental [Page 41]
pascal@12756	2299
pascal@12756	2300 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2301
pascal@12756	2302
pascal@12756	2303 4.6.5. Enhancing the excitation
pascal@12756	2304
pascal@12756	2305 From the criterion in the previous section, it is clear that the
pascal@12756	2306 excitation is not allowed to change much. The purpose of this
pascal@12756	2307 constraint is to prevent the creation of an enhanced signal
pascal@12756	2308 significantly different from the original signal. This also means
pascal@12756	2309 that the constraint limits the numerical size of the errors that the
pascal@12756	2310 enhancement procedure can make. That is especially important in
pascal@12756	2311 unvoiced segments and background noise segments for which increased
pascal@12756	2312 periodicity could lead to lower perceived quality.
pascal@12756	2313
pascal@12756	2314 When the constraint in the prior section is not met, the enhanced
pascal@12756	2315 residual is instead calculated through a constrained optimization by
pascal@12756	2316 using the Lagrange multiplier technique. The new constraint is that
pascal@12756	2317
pascal@12756	2318 e = (b * \|\|pssq(0)\|\|^2) (Constraint 2)
pascal@12756	2319
pascal@12756	2320 We distinguish two solution regions for the optimization: 1) the
pascal@12756	2321 region where the first constraint is fulfilled and 2) the region
pascal@12756	2322 where the first constraint is not fulfilled and the second constraint
pascal@12756	2323 must be used.
pascal@12756	2324
pascal@12756	2325 In the first case, where the second constraint is not needed, the
pascal@12756	2326 optimized re-estimated vector is simply z, the energy-scaled version
pascal@12756	2327 of y.
pascal@12756	2328
pascal@12756	2329 In the second case, where the second constraint is activated and
pascal@12756	2330 becomes an equality constraint, we have
pascal@12756	2331
pascal@12756	2332 z= Ay + Bpssq(0)
pascal@12756	2333
pascal@12756	2334 where
pascal@12756	2335
pascal@12756	2336 A = sqrt((b-b^2/4)(w00w00)/ (w11w00 + w10w10)) and
pascal@12756	2337
pascal@12756	2338 w11 = pssq(0)*pssq(0)
pascal@12756	2339 w00 = y*y
pascal@12756	2340 w10 = ypssq(0) ( symbolizes the dot product)
pascal@12756	2341
pascal@12756	2342 and
pascal@12756	2343
pascal@12756	2344 B = 1 - b/2 - A * w10/w00
pascal@12756	2345
pascal@12756	2346 Appendix A.16 contains a listing of a reference implementation for
pascal@12756	2347 the enhancement method.
pascal@12756	2348
pascal@12756	2349
pascal@12756	2350
pascal@12756	2351
pascal@12756	2352
pascal@12756	2353
pascal@12756	2354 Andersen, et al. Experimental [Page 42]
pascal@12756	2355
pascal@12756	2356 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2357
pascal@12756	2358
pascal@12756	2359 4.7. Synthesis Filtering
pascal@12756	2360
pascal@12756	2361 Upon decoding or PLC of the LP excitation block, the decoded speech
pascal@12756	2362 block is obtained by running the decoded LP synthesis filter,
pascal@12756	2363 1/A~k(z), over the block. The synthesis filters have to be shifted
pascal@12756	2364 to compensate for the delay in the enhancer. For 20 ms frame size
pascal@12756	2365 mode, they SHOULD be shifted one 40-sample sub-block, and for 30 ms
pascal@12756	2366 frame size mode, they SHOULD be shifted two 40-sample sub-blocks.
pascal@12756	2367 The LP coefficients SHOULD be changed at the first sample of every
pascal@12756	2368 sub-block while keeping the filter state. For PLC blocks, one
pascal@12756	2369 solution is to apply the last LP coefficients of the last decoded
pascal@12756	2370 speech block for all sub-blocks.
pascal@12756	2371
pascal@12756	2372 The reference implementation for the synthesis filtering can be found
pascal@12756	2373 in Appendix A.48.
pascal@12756	2374
pascal@12756	2375 4.8. Post Filtering
pascal@12756	2376
pascal@12756	2377 If desired, the decoded block can be filtered by a high-pass filter.
pascal@12756	2378 This removes the low frequencies of the decoded signal. A reference
pascal@12756	2379 implementation of this, with cutoff at 65 Hz, is shown in Appendix
pascal@12756	2380 A.30.
pascal@12756	2381
pascal@12756	2382 5. Security Considerations
pascal@12756	2383
pascal@12756	2384 This algorithm for the coding of speech signals is not subject to any
pascal@12756	2385 known security consideration; however, its RTP payload format [1] is
pascal@12756	2386 subject to several considerations, which are addressed there.
pascal@12756	2387 Confidentiality of the media streams is achieved by encryption;
pascal@12756	2388 therefore external mechanisms, such as SRTP [5], MAY be used for that
pascal@12756	2389 purpose.
pascal@12756	2390
pascal@12756	2391 6. Evaluation of the iLBC Implementations
pascal@12756	2392
pascal@12756	2393 It is possible and suggested to evaluate certain iLBC implementation
pascal@12756	2394 by utilizing methodology and tools available at
pascal@12756	2395 http://www.ilbcfreeware.org/evaluation.html
pascal@12756	2396
pascal@12756	2397 7. References
pascal@12756	2398
pascal@12756	2399 7.1. Normative References
pascal@12756	2400
pascal@12756	2401 [1] Duric, A. and S. Andersen, "Real-time Transport Protocol (RTP)
pascal@12756	2402 Payload Format for internet Low Bit Rate Codec (iLBC) Speech",
pascal@12756	2403 RFC 3952, December 2004.
pascal@12756	2404
pascal@12756	2405 [2] Bradner, S., "Key words for use in RFCs to Indicate Requirement
pascal@12756	2406 Levels", BCP 14, RFC 2119, March 1997.
pascal@12756	2407
pascal@12756	2408
pascal@12756	2409
pascal@12756	2410 Andersen, et al. Experimental [Page 43]
pascal@12756	2411
pascal@12756	2412 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2413
pascal@12756	2414
pascal@12756	2415 [3] PacketCable(TM) Audio/Video Codecs Specification, Cable
pascal@12756	2416 Television Laboratories, Inc.
pascal@12756	2417
pascal@12756	2418 7.2. Informative References
pascal@12756	2419
pascal@12756	2420 [4] ITU-T Recommendation G.711, available online from the ITU
pascal@12756	2421 bookstore at http://www.itu.int.
pascal@12756	2422
pascal@12756	2423 [5] Baugher, M., McGrew, D., Naslund, M., Carrara, E., and K. Norman,
pascal@12756	2424 "The Secure Real Time Transport Protocol (SRTP)", RFC 3711, March
pascal@12756	2425 2004.
pascal@12756	2426
pascal@12756	2427 8. Acknowledgements
pascal@12756	2428
pascal@12756	2429 This extensive work, besides listed authors, has the following
pascal@12756	2430 authors, who could not have been listed among "official" authors (due
pascal@12756	2431 to IESG restrictions in the number of authors who can be listed):
pascal@12756	2432
pascal@12756	2433 Manohar N. Murthi (Department of Electrical and Computer
pascal@12756	2434 Engineering, University of Miami), Fredrik Galschiodt, Julian
pascal@12756	2435 Spittka, and Jan Skoglund (Global IP Sound).
pascal@12756	2436
pascal@12756	2437 The authors are deeply indebted to the following people and thank
pascal@12756	2438 them sincerely:
pascal@12756	2439
pascal@12756	2440 Henry Sinnreich, Patrik Faltstrom, Alan Johnston, and Jean-
pascal@12756	2441 Francois Mule for great support of the iLBC initiative and for
pascal@12756	2442 valuable feedback and comments.
pascal@12756	2443
pascal@12756	2444 Peter Vary, Frank Mertz, and Christoph Erdmann (RWTH Aachen);
pascal@12756	2445 Vladimir Cuperman (Niftybox LLC); Thomas Eriksson (Chalmers Univ
pascal@12756	2446 of Tech), and Gernot Kubin (TU Graz), for thorough review of the
pascal@12756	2447 iLBC document and their valuable feedback and remarks.
pascal@12756	2448
pascal@12756	2449
pascal@12756	2450
pascal@12756	2451
pascal@12756	2452
pascal@12756	2453
pascal@12756	2454
pascal@12756	2455
pascal@12756	2456
pascal@12756	2457
pascal@12756	2458
pascal@12756	2459
pascal@12756	2460
pascal@12756	2461
pascal@12756	2462
pascal@12756	2463
pascal@12756	2464
pascal@12756	2465
pascal@12756	2466 Andersen, et al. Experimental [Page 44]
pascal@12756	2467
pascal@12756	2468 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2469
pascal@12756	2470
pascal@12756	2471 APPENDIX A. Reference Implementation
pascal@12756	2472
pascal@12756	2473 This appendix contains the complete c-code for a reference
pascal@12756	2474 implementation of encoder and decoder for the specified codec.
pascal@12756	2475
pascal@12756	2476 The c-code consists of the following files with highest-level
pascal@12756	2477 functions:
pascal@12756	2478
pascal@12756	2479 iLBC_test.c: main function for evaluation purpose
pascal@12756	2480 iLBC_encode.h: encoder header
pascal@12756	2481 iLBC_encode.c: encoder function
pascal@12756	2482 iLBC_decode.h: decoder header
pascal@12756	2483 iLBC_decode.c: decoder function
pascal@12756	2484
pascal@12756	2485 The following files contain global defines and constants:
pascal@12756	2486
pascal@12756	2487 iLBC_define.h: global defines
pascal@12756	2488 constants.h: global constants header
pascal@12756	2489 constants.c: global constants memory allocations
pascal@12756	2490
pascal@12756	2491 The following files contain subroutines:
pascal@12756	2492
pascal@12756	2493 anaFilter.h: lpc analysis filter header
pascal@12756	2494 anaFilter.c: lpc analysis filter function
pascal@12756	2495 createCB.h: codebook construction header
pascal@12756	2496 createCB.c: codebook construction function
pascal@12756	2497 doCPLC.h: packet loss concealment header
pascal@12756	2498 doCPLC.c: packet loss concealment function
pascal@12756	2499 enhancer.h: signal enhancement header
pascal@12756	2500 enhancer.c: signal enhancement function
pascal@12756	2501 filter.h: general filter header
pascal@12756	2502 filter.c: general filter functions
pascal@12756	2503 FrameClassify.h: start state classification header
pascal@12756	2504 FrameClassify.c: start state classification function
pascal@12756	2505 gainquant.h: gain quantization header
pascal@12756	2506 gainquant.c: gain quantization function
pascal@12756	2507 getCBvec.h: codebook vector construction header
pascal@12756	2508 getCBvec.c: codebook vector construction function
pascal@12756	2509 helpfun.h: general purpose header
pascal@12756	2510 helpfun.c: general purpose functions
pascal@12756	2511 hpInput.h: input high pass filter header
pascal@12756	2512 hpInput.c: input high pass filter function
pascal@12756	2513 hpOutput.h: output high pass filter header
pascal@12756	2514 hpOutput.c: output high pass filter function
pascal@12756	2515 iCBConstruct.h: excitation decoding header
pascal@12756	2516 iCBConstruct.c: excitation decoding function
pascal@12756	2517 iCBSearch.h: excitation encoding header
pascal@12756	2518 iCBSearch.c: excitation encoding function
pascal@12756	2519
pascal@12756	2520
pascal@12756	2521
pascal@12756	2522 Andersen, et al. Experimental [Page 45]
pascal@12756	2523
pascal@12756	2524 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2525
pascal@12756	2526
pascal@12756	2527 LPCdecode.h: lpc decoding header
pascal@12756	2528 LPCdecode.c: lpc decoding function
pascal@12756	2529 LPCencode.h: lpc encoding header
pascal@12756	2530 LPCencode.c: lpc encoding function
pascal@12756	2531 lsf.h: line spectral frequencies header
pascal@12756	2532 lsf.c: line spectral frequencies functions
pascal@12756	2533 packing.h: bitstream packetization header
pascal@12756	2534 packing.c: bitstream packetization functions
pascal@12756	2535 StateConstructW.h: state decoding header
pascal@12756	2536 StateConstructW.c: state decoding functions
pascal@12756	2537 StateSearchW.h: state encoding header
pascal@12756	2538 StateSearchW.c: state encoding function
pascal@12756	2539 syntFilter.h: lpc synthesis filter header
pascal@12756	2540 syntFilter.c: lpc synthesis filter function
pascal@12756	2541
pascal@12756	2542 The implementation is portable and should work on many different
pascal@12756	2543 platforms. However, it is not difficult to optimize the
pascal@12756	2544 implementation on particular platforms, an exercise left to the
pascal@12756	2545 reader.
pascal@12756	2546
pascal@12756	2547 A.1. iLBC_test.c
pascal@12756	2548
pascal@12756	2549 /******************************************************************
pascal@12756	2550
pascal@12756	2551 iLBC Speech Coder ANSI-C Source Code
pascal@12756	2552
pascal@12756	2553 iLBC_test.c
pascal@12756	2554
pascal@12756	2555 Copyright (C) The Internet Society (2004).
pascal@12756	2556 All Rights Reserved.
pascal@12756	2557
pascal@12756	2558 ******************************************************************/
pascal@12756	2559
pascal@12756	2560 #include <math.h>
pascal@12756	2561 #include <stdlib.h>
pascal@12756	2562 #include <stdio.h>
pascal@12756	2563 #include <string.h>
pascal@12756	2564 #include "iLBC_define.h"
pascal@12756	2565 #include "iLBC_encode.h"
pascal@12756	2566 #include "iLBC_decode.h"
pascal@12756	2567
pascal@12756	2568 /* Runtime statistics */
pascal@12756	2569 #include <time.h>
pascal@12756	2570
pascal@12756	2571 #define ILBCNOOFWORDS_MAX (NO_OF_BYTES_30MS/2)
pascal@12756	2572
pascal@12756	2573 /----------------------------------------------------------------
pascal@12756	2574 * Encoder interface function
pascal@12756	2575
pascal@12756	2576
pascal@12756	2577
pascal@12756	2578 Andersen, et al. Experimental [Page 46]
pascal@12756	2579
pascal@12756	2580 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2581
pascal@12756	2582
pascal@12756	2583 ---------------------------------------------------------------/
pascal@12756	2584
pascal@12756	2585 short encode( /* (o) Number of bytes encoded */
pascal@12756	2586 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	2587 /* (i/o) Encoder instance */
pascal@12756	2588 short encoded_data, / (o) The encoded bytes */
pascal@12756	2589 short data / (i) The signal block to encode*/
pascal@12756	2590 ){
pascal@12756	2591 float block[BLOCKL_MAX];
pascal@12756	2592 int k;
pascal@12756	2593
pascal@12756	2594 /* convert signal to float */
pascal@12756	2595
pascal@12756	2596 for (k=0; k<iLBCenc_inst->blockl; k++)
pascal@12756	2597 block[k] = (float)data[k];
pascal@12756	2598
pascal@12756	2599 /* do the actual encoding */
pascal@12756	2600
pascal@12756	2601 iLBC_encode((unsigned char *)encoded_data, block, iLBCenc_inst);
pascal@12756	2602
pascal@12756	2603
pascal@12756	2604 return (iLBCenc_inst->no_of_bytes);
pascal@12756	2605 }
pascal@12756	2606
pascal@12756	2607 /----------------------------------------------------------------
pascal@12756	2608 * Decoder interface function
pascal@12756	2609 ---------------------------------------------------------------/
pascal@12756	2610
pascal@12756	2611 short decode( /* (o) Number of decoded samples */
pascal@12756	2612 iLBC_Dec_Inst_t iLBCdec_inst, / (i/o) Decoder instance */
pascal@12756	2613 short decoded_data, / (o) Decoded signal block*/
pascal@12756	2614 short encoded_data, / (i) Encoded bytes */
pascal@12756	2615 short mode /* (i) 0=PL, 1=Normal */
pascal@12756	2616 ){
pascal@12756	2617 int k;
pascal@12756	2618 float decblock[BLOCKL_MAX], dtmp;
pascal@12756	2619
pascal@12756	2620 /* check if mode is valid */
pascal@12756	2621
pascal@12756	2622 if (mode<0 \|\| mode>1) {
pascal@12756	2623 printf("\nERROR - Wrong mode - 0, 1 allowed\n"); exit(3);}
pascal@12756	2624
pascal@12756	2625 /* do actual decoding of block */
pascal@12756	2626
pascal@12756	2627 iLBC_decode(decblock, (unsigned char *)encoded_data,
pascal@12756	2628 iLBCdec_inst, mode);
pascal@12756	2629
pascal@12756	2630 /* convert to short */
pascal@12756	2631
pascal@12756	2632
pascal@12756	2633
pascal@12756	2634 Andersen, et al. Experimental [Page 47]
pascal@12756	2635
pascal@12756	2636 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2637
pascal@12756	2638
pascal@12756	2639 for (k=0; k<iLBCdec_inst->blockl; k++){
pascal@12756	2640 dtmp=decblock[k];
pascal@12756	2641
pascal@12756	2642 if (dtmp<MIN_SAMPLE)
pascal@12756	2643 dtmp=MIN_SAMPLE;
pascal@12756	2644 else if (dtmp>MAX_SAMPLE)
pascal@12756	2645 dtmp=MAX_SAMPLE;
pascal@12756	2646 decoded_data[k] = (short) dtmp;
pascal@12756	2647 }
pascal@12756	2648
pascal@12756	2649 return (iLBCdec_inst->blockl);
pascal@12756	2650 }
pascal@12756	2651
pascal@12756	2652 /---------------------------------------------------------------
pascal@12756	2653 * Main program to test iLBC encoding and decoding
pascal@12756	2654 *
pascal@12756	2655 * Usage:
pascal@12756	2656 * exefile_name.exe <infile> <bytefile> <outfile> <channel>
pascal@12756	2657 *
pascal@12756	2658 * <infile> : Input file, speech for encoder (16-bit pcm file)
pascal@12756	2659 * <bytefile> : Bit stream output from the encoder
pascal@12756	2660 * <outfile> : Output file, decoded speech (16-bit pcm file)
pascal@12756	2661 * <channel> : Bit error file, optional (16-bit)
pascal@12756	2662 * 1 - Packet received correctly
pascal@12756	2663 * 0 - Packet Lost
pascal@12756	2664 *
pascal@12756	2665 --------------------------------------------------------------/
pascal@12756	2666
pascal@12756	2667 int main(int argc, char* argv[])
pascal@12756	2668 {
pascal@12756	2669
pascal@12756	2670 /* Runtime statistics */
pascal@12756	2671
pascal@12756	2672 float starttime;
pascal@12756	2673 float runtime;
pascal@12756	2674 float outtime;
pascal@12756	2675
pascal@12756	2676 FILE ifileid,efileid,ofileid, cfileid;
pascal@12756	2677 short data[BLOCKL_MAX];
pascal@12756	2678 short encoded_data[ILBCNOOFWORDS_MAX], decoded_data[BLOCKL_MAX];
pascal@12756	2679 int len;
pascal@12756	2680 short pli, mode;
pascal@12756	2681 int blockcount = 0;
pascal@12756	2682 int packetlosscount = 0;
pascal@12756	2683
pascal@12756	2684 /* Create structs */
pascal@12756	2685 iLBC_Enc_Inst_t Enc_Inst;
pascal@12756	2686 iLBC_Dec_Inst_t Dec_Inst;
pascal@12756	2687
pascal@12756	2688
pascal@12756	2689
pascal@12756	2690 Andersen, et al. Experimental [Page 48]
pascal@12756	2691
pascal@12756	2692 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2693
pascal@12756	2694
pascal@12756	2695 /* get arguments and open files */
pascal@12756	2696
pascal@12756	2697 if ((argc!=5) && (argc!=6)) {
pascal@12756	2698 fprintf(stderr,
pascal@12756	2699 "\n-----------------------------------------------\n");
pascal@12756	2700 fprintf(stderr,
pascal@12756	2701 " %s <20,30> input encoded decoded (channel)\n\n",
pascal@12756	2702 argv[0]);
pascal@12756	2703 fprintf(stderr,
pascal@12756	2704 " mode : Frame size for the encoding/decoding\n");
pascal@12756	2705 fprintf(stderr,
pascal@12756	2706 " 20 - 20 ms\n");
pascal@12756	2707 fprintf(stderr,
pascal@12756	2708 " 30 - 30 ms\n");
pascal@12756	2709 fprintf(stderr,
pascal@12756	2710 " input : Speech for encoder (16-bit pcm file)\n");
pascal@12756	2711 fprintf(stderr,
pascal@12756	2712 " encoded : Encoded bit stream\n");
pascal@12756	2713 fprintf(stderr,
pascal@12756	2714 " decoded : Decoded speech (16-bit pcm file)\n");
pascal@12756	2715 fprintf(stderr,
pascal@12756	2716 " channel : Packet loss pattern, optional (16-bit)\n");
pascal@12756	2717 fprintf(stderr,
pascal@12756	2718 " 1 - Packet received correctly\n");
pascal@12756	2719 fprintf(stderr,
pascal@12756	2720 " 0 - Packet Lost\n");
pascal@12756	2721 fprintf(stderr,
pascal@12756	2722 "-----------------------------------------------\n\n");
pascal@12756	2723 exit(1);
pascal@12756	2724 }
pascal@12756	2725 mode=atoi(argv[1]);
pascal@12756	2726 if (mode != 20 && mode != 30) {
pascal@12756	2727 fprintf(stderr,"Wrong mode %s, must be 20, or 30\n",
pascal@12756	2728 argv[1]);
pascal@12756	2729 exit(2);
pascal@12756	2730 }
pascal@12756	2731 if ( (ifileid=fopen(argv[2],"rb")) == NULL) {
pascal@12756	2732 fprintf(stderr,"Cannot open input file %s\n", argv[2]);
pascal@12756	2733 exit(2);}
pascal@12756	2734 if ( (efileid=fopen(argv[3],"wb")) == NULL) {
pascal@12756	2735 fprintf(stderr, "Cannot open encoded file %s\n",
pascal@12756	2736 argv[3]); exit(1);}
pascal@12756	2737 if ( (ofileid=fopen(argv[4],"wb")) == NULL) {
pascal@12756	2738 fprintf(stderr, "Cannot open decoded file %s\n",
pascal@12756	2739 argv[4]); exit(1);}
pascal@12756	2740 if (argc==6) {
pascal@12756	2741 if( (cfileid=fopen(argv[5],"rb")) == NULL) {
pascal@12756	2742 fprintf(stderr, "Cannot open channel file %s\n",
pascal@12756	2743
pascal@12756	2744
pascal@12756	2745
pascal@12756	2746 Andersen, et al. Experimental [Page 49]
pascal@12756	2747
pascal@12756	2748 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2749
pascal@12756	2750
pascal@12756	2751 argv[5]);
pascal@12756	2752 exit(1);
pascal@12756	2753 }
pascal@12756	2754 } else {
pascal@12756	2755 cfileid=NULL;
pascal@12756	2756 }
pascal@12756	2757
pascal@12756	2758 /* print info */
pascal@12756	2759
pascal@12756	2760 fprintf(stderr, "\n");
pascal@12756	2761 fprintf(stderr,
pascal@12756	2762 "---------------------------------------------------\n");
pascal@12756	2763 fprintf(stderr,
pascal@12756	2764 "* *\n");
pascal@12756	2765 fprintf(stderr,
pascal@12756	2766 "* iLBC test program *\n");
pascal@12756	2767 fprintf(stderr,
pascal@12756	2768 "* *\n");
pascal@12756	2769 fprintf(stderr,
pascal@12756	2770 "* *\n");
pascal@12756	2771 fprintf(stderr,
pascal@12756	2772 "---------------------------------------------------\n");
pascal@12756	2773 fprintf(stderr,"\nMode : %2d ms\n", mode);
pascal@12756	2774 fprintf(stderr,"Input file : %s\n", argv[2]);
pascal@12756	2775 fprintf(stderr,"Encoded file : %s\n", argv[3]);
pascal@12756	2776 fprintf(stderr,"Output file : %s\n", argv[4]);
pascal@12756	2777 if (argc==6) {
pascal@12756	2778 fprintf(stderr,"Channel file : %s\n", argv[5]);
pascal@12756	2779 }
pascal@12756	2780 fprintf(stderr,"\n");
pascal@12756	2781
pascal@12756	2782 /* Initialization */
pascal@12756	2783
pascal@12756	2784 initEncode(&Enc_Inst, mode);
pascal@12756	2785 initDecode(&Dec_Inst, mode, 1);
pascal@12756	2786
pascal@12756	2787 /* Runtime statistics */
pascal@12756	2788
pascal@12756	2789 starttime=clock()/(float)CLOCKS_PER_SEC;
pascal@12756	2790
pascal@12756	2791 /* loop over input blocks */
pascal@12756	2792
pascal@12756	2793 while (fread(data,sizeof(short),Enc_Inst.blockl,ifileid)==
pascal@12756	2794 Enc_Inst.blockl) {
pascal@12756	2795
pascal@12756	2796 blockcount++;
pascal@12756	2797
pascal@12756	2798 /* encoding */
pascal@12756	2799
pascal@12756	2800
pascal@12756	2801
pascal@12756	2802 Andersen, et al. Experimental [Page 50]
pascal@12756	2803
pascal@12756	2804 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2805
pascal@12756	2806
pascal@12756	2807 fprintf(stderr, "--- Encoding block %i --- ",blockcount);
pascal@12756	2808 len=encode(&Enc_Inst, encoded_data, data);
pascal@12756	2809 fprintf(stderr, "\r");
pascal@12756	2810
pascal@12756	2811 /* write byte file */
pascal@12756	2812
pascal@12756	2813 fwrite(encoded_data, sizeof(unsigned char), len, efileid);
pascal@12756	2814
pascal@12756	2815 /* get channel data if provided */
pascal@12756	2816 if (argc==6) {
pascal@12756	2817 if (fread(&pli, sizeof(short), 1, cfileid)) {
pascal@12756	2818 if ((pli!=0)&&(pli!=1)) {
pascal@12756	2819 fprintf(stderr, "Error in channel file\n");
pascal@12756	2820 exit(0);
pascal@12756	2821 }
pascal@12756	2822 if (pli==0) {
pascal@12756	2823 /* Packet loss -> remove info from frame */
pascal@12756	2824 memset(encoded_data, 0,
pascal@12756	2825 sizeof(short)*ILBCNOOFWORDS_MAX);
pascal@12756	2826 packetlosscount++;
pascal@12756	2827 }
pascal@12756	2828 } else {
pascal@12756	2829 fprintf(stderr, "Error. Channel file too short\n");
pascal@12756	2830 exit(0);
pascal@12756	2831 }
pascal@12756	2832 } else {
pascal@12756	2833 pli=1;
pascal@12756	2834 }
pascal@12756	2835
pascal@12756	2836 /* decoding */
pascal@12756	2837
pascal@12756	2838 fprintf(stderr, "--- Decoding block %i --- ",blockcount);
pascal@12756	2839
pascal@12756	2840 len=decode(&Dec_Inst, decoded_data, encoded_data, pli);
pascal@12756	2841 fprintf(stderr, "\r");
pascal@12756	2842
pascal@12756	2843 /* write output file */
pascal@12756	2844
pascal@12756	2845 fwrite(decoded_data,sizeof(short),len,ofileid);
pascal@12756	2846 }
pascal@12756	2847
pascal@12756	2848 /* Runtime statistics */
pascal@12756	2849
pascal@12756	2850 runtime = (float)(clock()/(float)CLOCKS_PER_SEC-starttime);
pascal@12756	2851 outtime = (float)((float)blockcount*(float)mode/1000.0);
pascal@12756	2852 printf("\n\nLength of speech file: %.1f s\n", outtime);
pascal@12756	2853 printf("Packet loss : %.1f%%\n",
pascal@12756	2854 100.0*(float)packetlosscount/(float)blockcount);
pascal@12756	2855
pascal@12756	2856
pascal@12756	2857
pascal@12756	2858 Andersen, et al. Experimental [Page 51]
pascal@12756	2859
pascal@12756	2860 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2861
pascal@12756	2862
pascal@12756	2863 printf("Time to run iLBC :");
pascal@12756	2864 printf(" %.1f s (%.1f %% of realtime)\n\n", runtime,
pascal@12756	2865 (100*runtime/outtime));
pascal@12756	2866
pascal@12756	2867 /* close files */
pascal@12756	2868
pascal@12756	2869 fclose(ifileid); fclose(efileid); fclose(ofileid);
pascal@12756	2870 if (argc==6) {
pascal@12756	2871 fclose(cfileid);
pascal@12756	2872 }
pascal@12756	2873 return(0);
pascal@12756	2874 }
pascal@12756	2875
pascal@12756	2876 A.2. iLBC_encode.h
pascal@12756	2877
pascal@12756	2878 /******************************************************************
pascal@12756	2879
pascal@12756	2880 iLBC Speech Coder ANSI-C Source Code
pascal@12756	2881
pascal@12756	2882 iLBC_encode.h
pascal@12756	2883
pascal@12756	2884 Copyright (C) The Internet Society (2004).
pascal@12756	2885 All Rights Reserved.
pascal@12756	2886
pascal@12756	2887 ******************************************************************/
pascal@12756	2888
pascal@12756	2889 #ifndef __iLBC_ILBCENCODE_H
pascal@12756	2890 #define __iLBC_ILBCENCODE_H
pascal@12756	2891
pascal@12756	2892 #include "iLBC_define.h"
pascal@12756	2893
pascal@12756	2894 short initEncode( /* (o) Number of bytes
pascal@12756	2895 encoded */
pascal@12756	2896 iLBC_Enc_Inst_t iLBCenc_inst, / (i/o) Encoder instance */
pascal@12756	2897 int mode /* (i) frame size mode */
pascal@12756	2898 );
pascal@12756	2899
pascal@12756	2900 void iLBC_encode(
pascal@12756	2901
pascal@12756	2902 unsigned char bytes, / (o) encoded data bits iLBC */
pascal@12756	2903 float block, / (o) speech vector to
pascal@12756	2904 encode */
pascal@12756	2905 iLBC_Enc_Inst_t iLBCenc_inst / (i/o) the general encoder
pascal@12756	2906 state */
pascal@12756	2907 );
pascal@12756	2908
pascal@12756	2909 #endif
pascal@12756	2910
pascal@12756	2911
pascal@12756	2912
pascal@12756	2913
pascal@12756	2914 Andersen, et al. Experimental [Page 52]
pascal@12756	2915
pascal@12756	2916 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2917
pascal@12756	2918
pascal@12756	2919 A.3. iLBC_encode.c
pascal@12756	2920
pascal@12756	2921 /******************************************************************
pascal@12756	2922
pascal@12756	2923 iLBC Speech Coder ANSI-C Source Code
pascal@12756	2924
pascal@12756	2925 iLBC_encode.c
pascal@12756	2926
pascal@12756	2927 Copyright (C) The Internet Society (2004).
pascal@12756	2928 All Rights Reserved.
pascal@12756	2929
pascal@12756	2930 ******************************************************************/
pascal@12756	2931
pascal@12756	2932 #include <math.h>
pascal@12756	2933 #include <stdlib.h>
pascal@12756	2934 #include <string.h>
pascal@12756	2935
pascal@12756	2936 #include "iLBC_define.h"
pascal@12756	2937 #include "LPCencode.h"
pascal@12756	2938 #include "FrameClassify.h"
pascal@12756	2939 #include "StateSearchW.h"
pascal@12756	2940 #include "StateConstructW.h"
pascal@12756	2941 #include "helpfun.h"
pascal@12756	2942 #include "constants.h"
pascal@12756	2943 #include "packing.h"
pascal@12756	2944 #include "iCBSearch.h"
pascal@12756	2945 #include "iCBConstruct.h"
pascal@12756	2946 #include "hpInput.h"
pascal@12756	2947 #include "anaFilter.h"
pascal@12756	2948 #include "syntFilter.h"
pascal@12756	2949
pascal@12756	2950 /----------------------------------------------------------------
pascal@12756	2951 * Initiation of encoder instance.
pascal@12756	2952 ---------------------------------------------------------------/
pascal@12756	2953
pascal@12756	2954 short initEncode( /* (o) Number of bytes
pascal@12756	2955 encoded */
pascal@12756	2956 iLBC_Enc_Inst_t iLBCenc_inst, / (i/o) Encoder instance */
pascal@12756	2957 int mode /* (i) frame size mode */
pascal@12756	2958 ){
pascal@12756	2959 iLBCenc_inst->mode = mode;
pascal@12756	2960 if (mode==30) {
pascal@12756	2961 iLBCenc_inst->blockl = BLOCKL_30MS;
pascal@12756	2962 iLBCenc_inst->nsub = NSUB_30MS;
pascal@12756	2963 iLBCenc_inst->nasub = NASUB_30MS;
pascal@12756	2964 iLBCenc_inst->lpc_n = LPC_N_30MS;
pascal@12756	2965 iLBCenc_inst->no_of_bytes = NO_OF_BYTES_30MS;
pascal@12756	2966 iLBCenc_inst->no_of_words = NO_OF_WORDS_30MS;
pascal@12756	2967
pascal@12756	2968
pascal@12756	2969
pascal@12756	2970 Andersen, et al. Experimental [Page 53]
pascal@12756	2971
pascal@12756	2972 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	2973
pascal@12756	2974
pascal@12756	2975 iLBCenc_inst->state_short_len=STATE_SHORT_LEN_30MS;
pascal@12756	2976 /* ULP init */
pascal@12756	2977 iLBCenc_inst->ULP_inst=&ULP_30msTbl;
pascal@12756	2978 }
pascal@12756	2979 else if (mode==20) {
pascal@12756	2980 iLBCenc_inst->blockl = BLOCKL_20MS;
pascal@12756	2981 iLBCenc_inst->nsub = NSUB_20MS;
pascal@12756	2982 iLBCenc_inst->nasub = NASUB_20MS;
pascal@12756	2983 iLBCenc_inst->lpc_n = LPC_N_20MS;
pascal@12756	2984 iLBCenc_inst->no_of_bytes = NO_OF_BYTES_20MS;
pascal@12756	2985 iLBCenc_inst->no_of_words = NO_OF_WORDS_20MS;
pascal@12756	2986 iLBCenc_inst->state_short_len=STATE_SHORT_LEN_20MS;
pascal@12756	2987 /* ULP init */
pascal@12756	2988 iLBCenc_inst->ULP_inst=&ULP_20msTbl;
pascal@12756	2989 }
pascal@12756	2990 else {
pascal@12756	2991 exit(2);
pascal@12756	2992 }
pascal@12756	2993
pascal@12756	2994 memset((*iLBCenc_inst).anaMem, 0,
pascal@12756	2995 LPC_FILTERORDER*sizeof(float));
pascal@12756	2996 memcpy((*iLBCenc_inst).lsfold, lsfmeanTbl,
pascal@12756	2997 LPC_FILTERORDER*sizeof(float));
pascal@12756	2998 memcpy((*iLBCenc_inst).lsfdeqold, lsfmeanTbl,
pascal@12756	2999 LPC_FILTERORDER*sizeof(float));
pascal@12756	3000 memset((*iLBCenc_inst).lpc_buffer, 0,
pascal@12756	3001 (LPC_LOOKBACK+BLOCKL_MAX)*sizeof(float));
pascal@12756	3002 memset((iLBCenc_inst).hpimem, 0, 4sizeof(float));
pascal@12756	3003
pascal@12756	3004 return (iLBCenc_inst->no_of_bytes);
pascal@12756	3005 }
pascal@12756	3006
pascal@12756	3007 /----------------------------------------------------------------
pascal@12756	3008 * main encoder function
pascal@12756	3009 ---------------------------------------------------------------/
pascal@12756	3010
pascal@12756	3011 void iLBC_encode(
pascal@12756	3012 unsigned char bytes, / (o) encoded data bits iLBC */
pascal@12756	3013 float block, / (o) speech vector to
pascal@12756	3014 encode */
pascal@12756	3015 iLBC_Enc_Inst_t iLBCenc_inst / (i/o) the general encoder
pascal@12756	3016 state */
pascal@12756	3017 ){
pascal@12756	3018
pascal@12756	3019 float data[BLOCKL_MAX];
pascal@12756	3020 float residual[BLOCKL_MAX], reverseResidual[BLOCKL_MAX];
pascal@12756	3021
pascal@12756	3022 int start, idxForMax, idxVec[STATE_LEN];
pascal@12756	3023
pascal@12756	3024
pascal@12756	3025
pascal@12756	3026 Andersen, et al. Experimental [Page 54]
pascal@12756	3027
pascal@12756	3028 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3029
pascal@12756	3030
pascal@12756	3031 float reverseDecresidual[BLOCKL_MAX], mem[CB_MEML];
pascal@12756	3032 int n, k, meml_gotten, Nfor, Nback, i, pos;
pascal@12756	3033 int gain_index[CB_NSTAGES*NASUB_MAX],
pascal@12756	3034 extra_gain_index[CB_NSTAGES];
pascal@12756	3035 int cb_index[CB_NSTAGES*NASUB_MAX],extra_cb_index[CB_NSTAGES];
pascal@12756	3036 int lsf_i[LSF_NSPLIT*LPC_N_MAX];
pascal@12756	3037 unsigned char *pbytes;
pascal@12756	3038 int diff, start_pos, state_first;
pascal@12756	3039 float en1, en2;
pascal@12756	3040 int index, ulp, firstpart;
pascal@12756	3041 int subcount, subframe;
pascal@12756	3042 float weightState[LPC_FILTERORDER];
pascal@12756	3043 float syntdenum[NSUB_MAX*(LPC_FILTERORDER+1)];
pascal@12756	3044 float weightdenum[NSUB_MAX*(LPC_FILTERORDER+1)];
pascal@12756	3045 float decresidual[BLOCKL_MAX];
pascal@12756	3046
pascal@12756	3047 /* high pass filtering of input signal if such is not done
pascal@12756	3048 prior to calling this function */
pascal@12756	3049
pascal@12756	3050 hpInput(block, iLBCenc_inst->blockl,
pascal@12756	3051 data, (*iLBCenc_inst).hpimem);
pascal@12756	3052
pascal@12756	3053 /* otherwise simply copy */
pascal@12756	3054
pascal@12756	3055 /memcpy(data,block,iLBCenc_inst->blocklsizeof(float));*/
pascal@12756	3056
pascal@12756	3057 /* LPC of hp filtered input data */
pascal@12756	3058
pascal@12756	3059 LPCencode(syntdenum, weightdenum, lsf_i, data, iLBCenc_inst);
pascal@12756	3060
pascal@12756	3061
pascal@12756	3062 /* inverse filter to get residual */
pascal@12756	3063
pascal@12756	3064 for (n=0; n<iLBCenc_inst->nsub; n++) {
pascal@12756	3065 anaFilter(&data[nSUBL], &syntdenum[n(LPC_FILTERORDER+1)],
pascal@12756	3066 SUBL, &residual[n*SUBL], iLBCenc_inst->anaMem);
pascal@12756	3067 }
pascal@12756	3068
pascal@12756	3069 /* find state location */
pascal@12756	3070
pascal@12756	3071 start = FrameClassify(iLBCenc_inst, residual);
pascal@12756	3072
pascal@12756	3073 /* check if state should be in first or last part of the
pascal@12756	3074 two subframes */
pascal@12756	3075
pascal@12756	3076 diff = STATE_LEN - iLBCenc_inst->state_short_len;
pascal@12756	3077 en1 = 0;
pascal@12756	3078 index = (start-1)*SUBL;
pascal@12756	3079
pascal@12756	3080
pascal@12756	3081
pascal@12756	3082 Andersen, et al. Experimental [Page 55]
pascal@12756	3083
pascal@12756	3084 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3085
pascal@12756	3086
pascal@12756	3087 for (i = 0; i < iLBCenc_inst->state_short_len; i++) {
pascal@12756	3088 en1 += residual[index+i]*residual[index+i];
pascal@12756	3089 }
pascal@12756	3090 en2 = 0;
pascal@12756	3091 index = (start-1)*SUBL+diff;
pascal@12756	3092 for (i = 0; i < iLBCenc_inst->state_short_len; i++) {
pascal@12756	3093 en2 += residual[index+i]*residual[index+i];
pascal@12756	3094 }
pascal@12756	3095
pascal@12756	3096
pascal@12756	3097 if (en1 > en2) {
pascal@12756	3098 state_first = 1;
pascal@12756	3099 start_pos = (start-1)*SUBL;
pascal@12756	3100 } else {
pascal@12756	3101 state_first = 0;
pascal@12756	3102 start_pos = (start-1)*SUBL + diff;
pascal@12756	3103 }
pascal@12756	3104
pascal@12756	3105 /* scalar quantization of state */
pascal@12756	3106
pascal@12756	3107 StateSearchW(iLBCenc_inst, &residual[start_pos],
pascal@12756	3108 &syntdenum[(start-1)*(LPC_FILTERORDER+1)],
pascal@12756	3109 &weightdenum[(start-1)*(LPC_FILTERORDER+1)], &idxForMax,
pascal@12756	3110 idxVec, iLBCenc_inst->state_short_len, state_first);
pascal@12756	3111
pascal@12756	3112 StateConstructW(idxForMax, idxVec,
pascal@12756	3113 &syntdenum[(start-1)*(LPC_FILTERORDER+1)],
pascal@12756	3114 &decresidual[start_pos], iLBCenc_inst->state_short_len);
pascal@12756	3115
pascal@12756	3116 /* predictive quantization in state */
pascal@12756	3117
pascal@12756	3118 if (state_first) { /* put adaptive part in the end */
pascal@12756	3119
pascal@12756	3120 /* setup memory */
pascal@12756	3121
pascal@12756	3122 memset(mem, 0,
pascal@12756	3123 (CB_MEML-iLBCenc_inst->state_short_len)*sizeof(float));
pascal@12756	3124 memcpy(mem+CB_MEML-iLBCenc_inst->state_short_len,
pascal@12756	3125 decresidual+start_pos,
pascal@12756	3126 iLBCenc_inst->state_short_len*sizeof(float));
pascal@12756	3127 memset(weightState, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	3128
pascal@12756	3129 /* encode sub-frames */
pascal@12756	3130
pascal@12756	3131 iCBSearch(iLBCenc_inst, extra_cb_index, extra_gain_index,
pascal@12756	3132 &residual[start_pos+iLBCenc_inst->state_short_len],
pascal@12756	3133 mem+CB_MEML-stMemLTbl,
pascal@12756	3134 stMemLTbl, diff, CB_NSTAGES,
pascal@12756	3135
pascal@12756	3136
pascal@12756	3137
pascal@12756	3138 Andersen, et al. Experimental [Page 56]
pascal@12756	3139
pascal@12756	3140 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3141
pascal@12756	3142
pascal@12756	3143 &weightdenum[start*(LPC_FILTERORDER+1)],
pascal@12756	3144 weightState, 0);
pascal@12756	3145
pascal@12756	3146 /* construct decoded vector */
pascal@12756	3147
pascal@12756	3148 iCBConstruct(
pascal@12756	3149 &decresidual[start_pos+iLBCenc_inst->state_short_len],
pascal@12756	3150 extra_cb_index, extra_gain_index,
pascal@12756	3151 mem+CB_MEML-stMemLTbl,
pascal@12756	3152 stMemLTbl, diff, CB_NSTAGES);
pascal@12756	3153
pascal@12756	3154 }
pascal@12756	3155 else { /* put adaptive part in the beginning */
pascal@12756	3156
pascal@12756	3157 /* create reversed vectors for prediction */
pascal@12756	3158
pascal@12756	3159 for (k=0; k<diff; k++) {
pascal@12756	3160 reverseResidual[k] = residual[(start+1)*SUBL-1
pascal@12756	3161 -(k+iLBCenc_inst->state_short_len)];
pascal@12756	3162 }
pascal@12756	3163
pascal@12756	3164 /* setup memory */
pascal@12756	3165
pascal@12756	3166 meml_gotten = iLBCenc_inst->state_short_len;
pascal@12756	3167 for (k=0; k<meml_gotten; k++) {
pascal@12756	3168 mem[CB_MEML-1-k] = decresidual[start_pos + k];
pascal@12756	3169 }
pascal@12756	3170 memset(mem, 0, (CB_MEML-k)*sizeof(float));
pascal@12756	3171 memset(weightState, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	3172
pascal@12756	3173 /* encode sub-frames */
pascal@12756	3174
pascal@12756	3175 iCBSearch(iLBCenc_inst, extra_cb_index, extra_gain_index,
pascal@12756	3176 reverseResidual, mem+CB_MEML-stMemLTbl, stMemLTbl,
pascal@12756	3177 diff, CB_NSTAGES,
pascal@12756	3178 &weightdenum[(start-1)*(LPC_FILTERORDER+1)],
pascal@12756	3179 weightState, 0);
pascal@12756	3180
pascal@12756	3181 /* construct decoded vector */
pascal@12756	3182
pascal@12756	3183 iCBConstruct(reverseDecresidual, extra_cb_index,
pascal@12756	3184 extra_gain_index, mem+CB_MEML-stMemLTbl, stMemLTbl,
pascal@12756	3185 diff, CB_NSTAGES);
pascal@12756	3186
pascal@12756	3187 /* get decoded residual from reversed vector */
pascal@12756	3188
pascal@12756	3189 for (k=0; k<diff; k++) {
pascal@12756	3190 decresidual[start_pos-1-k] = reverseDecresidual[k];
pascal@12756	3191
pascal@12756	3192
pascal@12756	3193
pascal@12756	3194 Andersen, et al. Experimental [Page 57]
pascal@12756	3195
pascal@12756	3196 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3197
pascal@12756	3198
pascal@12756	3199 }
pascal@12756	3200 }
pascal@12756	3201
pascal@12756	3202 /* counter for predicted sub-frames */
pascal@12756	3203
pascal@12756	3204 subcount=0;
pascal@12756	3205
pascal@12756	3206 /* forward prediction of sub-frames */
pascal@12756	3207
pascal@12756	3208 Nfor = iLBCenc_inst->nsub-start-1;
pascal@12756	3209
pascal@12756	3210
pascal@12756	3211 if ( Nfor > 0 ) {
pascal@12756	3212
pascal@12756	3213 /* setup memory */
pascal@12756	3214
pascal@12756	3215 memset(mem, 0, (CB_MEML-STATE_LEN)*sizeof(float));
pascal@12756	3216 memcpy(mem+CB_MEML-STATE_LEN, decresidual+(start-1)*SUBL,
pascal@12756	3217 STATE_LEN*sizeof(float));
pascal@12756	3218 memset(weightState, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	3219
pascal@12756	3220 /* loop over sub-frames to encode */
pascal@12756	3221
pascal@12756	3222 for (subframe=0; subframe<Nfor; subframe++) {
pascal@12756	3223
pascal@12756	3224 /* encode sub-frame */
pascal@12756	3225
pascal@12756	3226 iCBSearch(iLBCenc_inst, cb_index+subcount*CB_NSTAGES,
pascal@12756	3227 gain_index+subcount*CB_NSTAGES,
pascal@12756	3228 &residual[(start+1+subframe)*SUBL],
pascal@12756	3229 mem+CB_MEML-memLfTbl[subcount],
pascal@12756	3230 memLfTbl[subcount], SUBL, CB_NSTAGES,
pascal@12756	3231 &weightdenum[(start+1+subframe)*
pascal@12756	3232 (LPC_FILTERORDER+1)],
pascal@12756	3233 weightState, subcount+1);
pascal@12756	3234
pascal@12756	3235 /* construct decoded vector */
pascal@12756	3236
pascal@12756	3237 iCBConstruct(&decresidual[(start+1+subframe)*SUBL],
pascal@12756	3238 cb_index+subcount*CB_NSTAGES,
pascal@12756	3239 gain_index+subcount*CB_NSTAGES,
pascal@12756	3240 mem+CB_MEML-memLfTbl[subcount],
pascal@12756	3241 memLfTbl[subcount], SUBL, CB_NSTAGES);
pascal@12756	3242
pascal@12756	3243 /* update memory */
pascal@12756	3244
pascal@12756	3245 memcpy(mem, mem+SUBL, (CB_MEML-SUBL)*sizeof(float));
pascal@12756	3246 memcpy(mem+CB_MEML-SUBL,
pascal@12756	3247
pascal@12756	3248
pascal@12756	3249
pascal@12756	3250 Andersen, et al. Experimental [Page 58]
pascal@12756	3251
pascal@12756	3252 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3253
pascal@12756	3254
pascal@12756	3255 &decresidual[(start+1+subframe)*SUBL],
pascal@12756	3256 SUBL*sizeof(float));
pascal@12756	3257 memset(weightState, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	3258
pascal@12756	3259 subcount++;
pascal@12756	3260 }
pascal@12756	3261 }
pascal@12756	3262
pascal@12756	3263
pascal@12756	3264 /* backward prediction of sub-frames */
pascal@12756	3265
pascal@12756	3266 Nback = start-1;
pascal@12756	3267
pascal@12756	3268
pascal@12756	3269 if ( Nback > 0 ) {
pascal@12756	3270
pascal@12756	3271 /* create reverse order vectors */
pascal@12756	3272
pascal@12756	3273 for (n=0; n<Nback; n++) {
pascal@12756	3274 for (k=0; k<SUBL; k++) {
pascal@12756	3275 reverseResidual[n*SUBL+k] =
pascal@12756	3276 residual[(start-1)SUBL-1-nSUBL-k];
pascal@12756	3277 reverseDecresidual[n*SUBL+k] =
pascal@12756	3278 decresidual[(start-1)SUBL-1-nSUBL-k];
pascal@12756	3279 }
pascal@12756	3280 }
pascal@12756	3281
pascal@12756	3282 /* setup memory */
pascal@12756	3283
pascal@12756	3284 meml_gotten = SUBL*(iLBCenc_inst->nsub+1-start);
pascal@12756	3285
pascal@12756	3286
pascal@12756	3287 if ( meml_gotten > CB_MEML ) {
pascal@12756	3288 meml_gotten=CB_MEML;
pascal@12756	3289 }
pascal@12756	3290 for (k=0; k<meml_gotten; k++) {
pascal@12756	3291 mem[CB_MEML-1-k] = decresidual[(start-1)*SUBL + k];
pascal@12756	3292 }
pascal@12756	3293 memset(mem, 0, (CB_MEML-k)*sizeof(float));
pascal@12756	3294 memset(weightState, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	3295
pascal@12756	3296 /* loop over sub-frames to encode */
pascal@12756	3297
pascal@12756	3298 for (subframe=0; subframe<Nback; subframe++) {
pascal@12756	3299
pascal@12756	3300 /* encode sub-frame */
pascal@12756	3301
pascal@12756	3302 iCBSearch(iLBCenc_inst, cb_index+subcount*CB_NSTAGES,
pascal@12756	3303
pascal@12756	3304
pascal@12756	3305
pascal@12756	3306 Andersen, et al. Experimental [Page 59]
pascal@12756	3307
pascal@12756	3308 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3309
pascal@12756	3310
pascal@12756	3311 gain_index+subcount*CB_NSTAGES,
pascal@12756	3312 &reverseResidual[subframe*SUBL],
pascal@12756	3313 mem+CB_MEML-memLfTbl[subcount],
pascal@12756	3314 memLfTbl[subcount], SUBL, CB_NSTAGES,
pascal@12756	3315 &weightdenum[(start-2-subframe)*
pascal@12756	3316 (LPC_FILTERORDER+1)],
pascal@12756	3317 weightState, subcount+1);
pascal@12756	3318
pascal@12756	3319 /* construct decoded vector */
pascal@12756	3320
pascal@12756	3321 iCBConstruct(&reverseDecresidual[subframe*SUBL],
pascal@12756	3322 cb_index+subcount*CB_NSTAGES,
pascal@12756	3323 gain_index+subcount*CB_NSTAGES,
pascal@12756	3324 mem+CB_MEML-memLfTbl[subcount],
pascal@12756	3325 memLfTbl[subcount], SUBL, CB_NSTAGES);
pascal@12756	3326
pascal@12756	3327 /* update memory */
pascal@12756	3328
pascal@12756	3329 memcpy(mem, mem+SUBL, (CB_MEML-SUBL)*sizeof(float));
pascal@12756	3330 memcpy(mem+CB_MEML-SUBL,
pascal@12756	3331 &reverseDecresidual[subframe*SUBL],
pascal@12756	3332 SUBL*sizeof(float));
pascal@12756	3333 memset(weightState, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	3334
pascal@12756	3335 subcount++;
pascal@12756	3336
pascal@12756	3337 }
pascal@12756	3338
pascal@12756	3339 /* get decoded residual from reversed vector */
pascal@12756	3340
pascal@12756	3341 for (i=0; i<SUBL*Nback; i++) {
pascal@12756	3342 decresidual[SUBL*Nback - i - 1] =
pascal@12756	3343 reverseDecresidual[i];
pascal@12756	3344 }
pascal@12756	3345 }
pascal@12756	3346 /* end encoding part */
pascal@12756	3347
pascal@12756	3348 /* adjust index */
pascal@12756	3349 index_conv_enc(cb_index);
pascal@12756	3350
pascal@12756	3351 /* pack bytes */
pascal@12756	3352
pascal@12756	3353 pbytes=bytes;
pascal@12756	3354 pos=0;
pascal@12756	3355
pascal@12756	3356 /* loop over the 3 ULP classes */
pascal@12756	3357
pascal@12756	3358 for (ulp=0; ulp<3; ulp++) {
pascal@12756	3359
pascal@12756	3360
pascal@12756	3361
pascal@12756	3362 Andersen, et al. Experimental [Page 60]
pascal@12756	3363
pascal@12756	3364 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3365
pascal@12756	3366
pascal@12756	3367
pascal@12756	3368 /* LSF */
pascal@12756	3369 for (k=0; k<LSF_NSPLIT*iLBCenc_inst->lpc_n; k++) {
pascal@12756	3370 packsplit(&lsf_i[k], &firstpart, &lsf_i[k],
pascal@12756	3371 iLBCenc_inst->ULP_inst->lsf_bits[k][ulp],
pascal@12756	3372 iLBCenc_inst->ULP_inst->lsf_bits[k][ulp]+
pascal@12756	3373 iLBCenc_inst->ULP_inst->lsf_bits[k][ulp+1]+
pascal@12756	3374 iLBCenc_inst->ULP_inst->lsf_bits[k][ulp+2]);
pascal@12756	3375 dopack( &pbytes, firstpart,
pascal@12756	3376 iLBCenc_inst->ULP_inst->lsf_bits[k][ulp], &pos);
pascal@12756	3377 }
pascal@12756	3378
pascal@12756	3379 /* Start block info */
pascal@12756	3380
pascal@12756	3381 packsplit(&start, &firstpart, &start,
pascal@12756	3382 iLBCenc_inst->ULP_inst->start_bits[ulp],
pascal@12756	3383 iLBCenc_inst->ULP_inst->start_bits[ulp]+
pascal@12756	3384 iLBCenc_inst->ULP_inst->start_bits[ulp+1]+
pascal@12756	3385 iLBCenc_inst->ULP_inst->start_bits[ulp+2]);
pascal@12756	3386 dopack( &pbytes, firstpart,
pascal@12756	3387 iLBCenc_inst->ULP_inst->start_bits[ulp], &pos);
pascal@12756	3388
pascal@12756	3389 packsplit(&state_first, &firstpart, &state_first,
pascal@12756	3390 iLBCenc_inst->ULP_inst->startfirst_bits[ulp],
pascal@12756	3391 iLBCenc_inst->ULP_inst->startfirst_bits[ulp]+
pascal@12756	3392 iLBCenc_inst->ULP_inst->startfirst_bits[ulp+1]+
pascal@12756	3393 iLBCenc_inst->ULP_inst->startfirst_bits[ulp+2]);
pascal@12756	3394 dopack( &pbytes, firstpart,
pascal@12756	3395 iLBCenc_inst->ULP_inst->startfirst_bits[ulp], &pos);
pascal@12756	3396
pascal@12756	3397 packsplit(&idxForMax, &firstpart, &idxForMax,
pascal@12756	3398 iLBCenc_inst->ULP_inst->scale_bits[ulp],
pascal@12756	3399 iLBCenc_inst->ULP_inst->scale_bits[ulp]+
pascal@12756	3400 iLBCenc_inst->ULP_inst->scale_bits[ulp+1]+
pascal@12756	3401 iLBCenc_inst->ULP_inst->scale_bits[ulp+2]);
pascal@12756	3402 dopack( &pbytes, firstpart,
pascal@12756	3403 iLBCenc_inst->ULP_inst->scale_bits[ulp], &pos);
pascal@12756	3404
pascal@12756	3405 for (k=0; k<iLBCenc_inst->state_short_len; k++) {
pascal@12756	3406 packsplit(idxVec+k, &firstpart, idxVec+k,
pascal@12756	3407 iLBCenc_inst->ULP_inst->state_bits[ulp],
pascal@12756	3408 iLBCenc_inst->ULP_inst->state_bits[ulp]+
pascal@12756	3409 iLBCenc_inst->ULP_inst->state_bits[ulp+1]+
pascal@12756	3410 iLBCenc_inst->ULP_inst->state_bits[ulp+2]);
pascal@12756	3411 dopack( &pbytes, firstpart,
pascal@12756	3412 iLBCenc_inst->ULP_inst->state_bits[ulp], &pos);
pascal@12756	3413 }
pascal@12756	3414
pascal@12756	3415
pascal@12756	3416
pascal@12756	3417
pascal@12756	3418 Andersen, et al. Experimental [Page 61]
pascal@12756	3419
pascal@12756	3420 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3421
pascal@12756	3422
pascal@12756	3423 /* 23/22 (20ms/30ms) sample block */
pascal@12756	3424
pascal@12756	3425 for (k=0;k<CB_NSTAGES;k++) {
pascal@12756	3426 packsplit(extra_cb_index+k, &firstpart,
pascal@12756	3427 extra_cb_index+k,
pascal@12756	3428 iLBCenc_inst->ULP_inst->extra_cb_index[k][ulp],
pascal@12756	3429 iLBCenc_inst->ULP_inst->extra_cb_index[k][ulp]+
pascal@12756	3430 iLBCenc_inst->ULP_inst->extra_cb_index[k][ulp+1]+
pascal@12756	3431 iLBCenc_inst->ULP_inst->extra_cb_index[k][ulp+2]);
pascal@12756	3432 dopack( &pbytes, firstpart,
pascal@12756	3433 iLBCenc_inst->ULP_inst->extra_cb_index[k][ulp],
pascal@12756	3434 &pos);
pascal@12756	3435 }
pascal@12756	3436
pascal@12756	3437 for (k=0;k<CB_NSTAGES;k++) {
pascal@12756	3438 packsplit(extra_gain_index+k, &firstpart,
pascal@12756	3439 extra_gain_index+k,
pascal@12756	3440 iLBCenc_inst->ULP_inst->extra_cb_gain[k][ulp],
pascal@12756	3441 iLBCenc_inst->ULP_inst->extra_cb_gain[k][ulp]+
pascal@12756	3442 iLBCenc_inst->ULP_inst->extra_cb_gain[k][ulp+1]+
pascal@12756	3443 iLBCenc_inst->ULP_inst->extra_cb_gain[k][ulp+2]);
pascal@12756	3444 dopack( &pbytes, firstpart,
pascal@12756	3445 iLBCenc_inst->ULP_inst->extra_cb_gain[k][ulp],
pascal@12756	3446 &pos);
pascal@12756	3447 }
pascal@12756	3448
pascal@12756	3449 /* The two/four (20ms/30ms) 40 sample sub-blocks */
pascal@12756	3450
pascal@12756	3451 for (i=0; i<iLBCenc_inst->nasub; i++) {
pascal@12756	3452 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	3453 packsplit(cb_index+i*CB_NSTAGES+k, &firstpart,
pascal@12756	3454 cb_index+i*CB_NSTAGES+k,
pascal@12756	3455 iLBCenc_inst->ULP_inst->cb_index[i][k][ulp],
pascal@12756	3456 iLBCenc_inst->ULP_inst->cb_index[i][k][ulp]+
pascal@12756	3457 iLBCenc_inst->ULP_inst->cb_index[i][k][ulp+1]+
pascal@12756	3458 iLBCenc_inst->ULP_inst->cb_index[i][k][ulp+2]);
pascal@12756	3459 dopack( &pbytes, firstpart,
pascal@12756	3460 iLBCenc_inst->ULP_inst->cb_index[i][k][ulp],
pascal@12756	3461 &pos);
pascal@12756	3462 }
pascal@12756	3463 }
pascal@12756	3464
pascal@12756	3465 for (i=0; i<iLBCenc_inst->nasub; i++) {
pascal@12756	3466 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	3467 packsplit(gain_index+i*CB_NSTAGES+k, &firstpart,
pascal@12756	3468 gain_index+i*CB_NSTAGES+k,
pascal@12756	3469 iLBCenc_inst->ULP_inst->cb_gain[i][k][ulp],
pascal@12756	3470 iLBCenc_inst->ULP_inst->cb_gain[i][k][ulp]+
pascal@12756	3471
pascal@12756	3472
pascal@12756	3473
pascal@12756	3474 Andersen, et al. Experimental [Page 62]
pascal@12756	3475
pascal@12756	3476 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3477
pascal@12756	3478
pascal@12756	3479 iLBCenc_inst->ULP_inst->cb_gain[i][k][ulp+1]+
pascal@12756	3480 iLBCenc_inst->ULP_inst->cb_gain[i][k][ulp+2]);
pascal@12756	3481 dopack( &pbytes, firstpart,
pascal@12756	3482 iLBCenc_inst->ULP_inst->cb_gain[i][k][ulp],
pascal@12756	3483 &pos);
pascal@12756	3484 }
pascal@12756	3485 }
pascal@12756	3486 }
pascal@12756	3487
pascal@12756	3488 /* set the last bit to zero (otherwise the decoder
pascal@12756	3489 will treat it as a lost frame) */
pascal@12756	3490 dopack( &pbytes, 0, 1, &pos);
pascal@12756	3491 }
pascal@12756	3492
pascal@12756	3493 A.4. iLBC_decode.h
pascal@12756	3494
pascal@12756	3495 /******************************************************************
pascal@12756	3496
pascal@12756	3497 iLBC Speech Coder ANSI-C Source Code
pascal@12756	3498
pascal@12756	3499 iLBC_decode.h
pascal@12756	3500
pascal@12756	3501 Copyright (C) The Internet Society (2004).
pascal@12756	3502 All Rights Reserved.
pascal@12756	3503
pascal@12756	3504 ******************************************************************/
pascal@12756	3505
pascal@12756	3506 #ifndef __iLBC_ILBCDECODE_H
pascal@12756	3507 #define __iLBC_ILBCDECODE_H
pascal@12756	3508
pascal@12756	3509 #include "iLBC_define.h"
pascal@12756	3510
pascal@12756	3511 short initDecode( /* (o) Number of decoded
pascal@12756	3512 samples */
pascal@12756	3513 iLBC_Dec_Inst_t iLBCdec_inst, / (i/o) Decoder instance */
pascal@12756	3514 int mode, /* (i) frame size mode */
pascal@12756	3515 int use_enhancer /* (i) 1 to use enhancer
pascal@12756	3516 0 to run without
pascal@12756	3517 enhancer */
pascal@12756	3518 );
pascal@12756	3519
pascal@12756	3520 void iLBC_decode(
pascal@12756	3521 float decblock, / (o) decoded signal block */
pascal@12756	3522 unsigned char bytes, / (i) encoded signal bits */
pascal@12756	3523 iLBC_Dec_Inst_t iLBCdec_inst, / (i/o) the decoder state
pascal@12756	3524 structure */
pascal@12756	3525 int mode /* (i) 0: bad packet, PLC,
pascal@12756	3526 1: normal */
pascal@12756	3527
pascal@12756	3528
pascal@12756	3529
pascal@12756	3530 Andersen, et al. Experimental [Page 63]
pascal@12756	3531
pascal@12756	3532 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3533
pascal@12756	3534
pascal@12756	3535 );
pascal@12756	3536
pascal@12756	3537 #endif
pascal@12756	3538
pascal@12756	3539 A.5. iLBC_decode.c
pascal@12756	3540
pascal@12756	3541 /******************************************************************
pascal@12756	3542
pascal@12756	3543 iLBC Speech Coder ANSI-C Source Code
pascal@12756	3544
pascal@12756	3545 iLBC_decode.c
pascal@12756	3546
pascal@12756	3547 Copyright (C) The Internet Society (2004).
pascal@12756	3548 All Rights Reserved.
pascal@12756	3549
pascal@12756	3550 ******************************************************************/
pascal@12756	3551
pascal@12756	3552 #include <math.h>
pascal@12756	3553 #include <stdlib.h>
pascal@12756	3554
pascal@12756	3555 #include "iLBC_define.h"
pascal@12756	3556 #include "StateConstructW.h"
pascal@12756	3557 #include "LPCdecode.h"
pascal@12756	3558 #include "iCBConstruct.h"
pascal@12756	3559 #include "doCPLC.h"
pascal@12756	3560 #include "helpfun.h"
pascal@12756	3561 #include "constants.h"
pascal@12756	3562 #include "packing.h"
pascal@12756	3563 #include "string.h"
pascal@12756	3564 #include "enhancer.h"
pascal@12756	3565 #include "hpOutput.h"
pascal@12756	3566 #include "syntFilter.h"
pascal@12756	3567
pascal@12756	3568 /----------------------------------------------------------------
pascal@12756	3569 * Initiation of decoder instance.
pascal@12756	3570 ---------------------------------------------------------------/
pascal@12756	3571
pascal@12756	3572 short initDecode( /* (o) Number of decoded
pascal@12756	3573 samples */
pascal@12756	3574 iLBC_Dec_Inst_t iLBCdec_inst, / (i/o) Decoder instance */
pascal@12756	3575 int mode, /* (i) frame size mode */
pascal@12756	3576 int use_enhancer /* (i) 1 to use enhancer
pascal@12756	3577 0 to run without
pascal@12756	3578 enhancer */
pascal@12756	3579 ){
pascal@12756	3580 int i;
pascal@12756	3581
pascal@12756	3582 iLBCdec_inst->mode = mode;
pascal@12756	3583
pascal@12756	3584
pascal@12756	3585
pascal@12756	3586 Andersen, et al. Experimental [Page 64]
pascal@12756	3587
pascal@12756	3588 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3589
pascal@12756	3590
pascal@12756	3591 if (mode==30) {
pascal@12756	3592 iLBCdec_inst->blockl = BLOCKL_30MS;
pascal@12756	3593 iLBCdec_inst->nsub = NSUB_30MS;
pascal@12756	3594 iLBCdec_inst->nasub = NASUB_30MS;
pascal@12756	3595 iLBCdec_inst->lpc_n = LPC_N_30MS;
pascal@12756	3596 iLBCdec_inst->no_of_bytes = NO_OF_BYTES_30MS;
pascal@12756	3597 iLBCdec_inst->no_of_words = NO_OF_WORDS_30MS;
pascal@12756	3598 iLBCdec_inst->state_short_len=STATE_SHORT_LEN_30MS;
pascal@12756	3599 /* ULP init */
pascal@12756	3600 iLBCdec_inst->ULP_inst=&ULP_30msTbl;
pascal@12756	3601 }
pascal@12756	3602 else if (mode==20) {
pascal@12756	3603 iLBCdec_inst->blockl = BLOCKL_20MS;
pascal@12756	3604 iLBCdec_inst->nsub = NSUB_20MS;
pascal@12756	3605 iLBCdec_inst->nasub = NASUB_20MS;
pascal@12756	3606 iLBCdec_inst->lpc_n = LPC_N_20MS;
pascal@12756	3607 iLBCdec_inst->no_of_bytes = NO_OF_BYTES_20MS;
pascal@12756	3608 iLBCdec_inst->no_of_words = NO_OF_WORDS_20MS;
pascal@12756	3609 iLBCdec_inst->state_short_len=STATE_SHORT_LEN_20MS;
pascal@12756	3610 /* ULP init */
pascal@12756	3611 iLBCdec_inst->ULP_inst=&ULP_20msTbl;
pascal@12756	3612 }
pascal@12756	3613 else {
pascal@12756	3614 exit(2);
pascal@12756	3615 }
pascal@12756	3616
pascal@12756	3617 memset(iLBCdec_inst->syntMem, 0,
pascal@12756	3618 LPC_FILTERORDER*sizeof(float));
pascal@12756	3619 memcpy((*iLBCdec_inst).lsfdeqold, lsfmeanTbl,
pascal@12756	3620 LPC_FILTERORDER*sizeof(float));
pascal@12756	3621
pascal@12756	3622 memset(iLBCdec_inst->old_syntdenum, 0,
pascal@12756	3623 ((LPC_FILTERORDER + 1)NSUB_MAX)sizeof(float));
pascal@12756	3624 for (i=0; i<NSUB_MAX; i++)
pascal@12756	3625 iLBCdec_inst->old_syntdenum[i*(LPC_FILTERORDER+1)]=1.0;
pascal@12756	3626
pascal@12756	3627 iLBCdec_inst->last_lag = 20;
pascal@12756	3628
pascal@12756	3629 iLBCdec_inst->prevLag = 120;
pascal@12756	3630 iLBCdec_inst->per = 0.0;
pascal@12756	3631 iLBCdec_inst->consPLICount = 0;
pascal@12756	3632 iLBCdec_inst->prevPLI = 0;
pascal@12756	3633 iLBCdec_inst->prevLpc[0] = 1.0;
pascal@12756	3634 memset(iLBCdec_inst->prevLpc+1,0,
pascal@12756	3635 LPC_FILTERORDER*sizeof(float));
pascal@12756	3636 memset(iLBCdec_inst->prevResidual, 0, BLOCKL_MAX*sizeof(float));
pascal@12756	3637 iLBCdec_inst->seed=777;
pascal@12756	3638
pascal@12756	3639
pascal@12756	3640
pascal@12756	3641
pascal@12756	3642 Andersen, et al. Experimental [Page 65]
pascal@12756	3643
pascal@12756	3644 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3645
pascal@12756	3646
pascal@12756	3647 memset(iLBCdec_inst->hpomem, 0, 4*sizeof(float));
pascal@12756	3648
pascal@12756	3649 iLBCdec_inst->use_enhancer = use_enhancer;
pascal@12756	3650 memset(iLBCdec_inst->enh_buf, 0, ENH_BUFL*sizeof(float));
pascal@12756	3651 for (i=0;i<ENH_NBLOCKS_TOT;i++)
pascal@12756	3652 iLBCdec_inst->enh_period[i]=(float)40.0;
pascal@12756	3653
pascal@12756	3654 iLBCdec_inst->prev_enh_pl = 0;
pascal@12756	3655
pascal@12756	3656 return (iLBCdec_inst->blockl);
pascal@12756	3657 }
pascal@12756	3658
pascal@12756	3659 /----------------------------------------------------------------
pascal@12756	3660 * frame residual decoder function (subrutine to iLBC_decode)
pascal@12756	3661 ---------------------------------------------------------------/
pascal@12756	3662
pascal@12756	3663 void Decode(
pascal@12756	3664 iLBC_Dec_Inst_t iLBCdec_inst, / (i/o) the decoder state
pascal@12756	3665 structure */
pascal@12756	3666 float decresidual, / (o) decoded residual frame */
pascal@12756	3667 int start, /* (i) location of start
pascal@12756	3668 state */
pascal@12756	3669 int idxForMax, /* (i) codebook index for the
pascal@12756	3670 maximum value */
pascal@12756	3671 int idxVec, / (i) codebook indexes for the
pascal@12756	3672 samples in the start
pascal@12756	3673 state */
pascal@12756	3674 float syntdenum, / (i) the decoded synthesis
pascal@12756	3675 filter coefficients */
pascal@12756	3676 int cb_index, / (i) the indexes for the
pascal@12756	3677 adaptive codebook */
pascal@12756	3678 int gain_index, / (i) the indexes for the
pascal@12756	3679 corresponding gains */
pascal@12756	3680 int extra_cb_index, / (i) the indexes for the
pascal@12756	3681 adaptive codebook part
pascal@12756	3682 of start state */
pascal@12756	3683 int extra_gain_index, / (i) the indexes for the
pascal@12756	3684 corresponding gains */
pascal@12756	3685 int state_first /* (i) 1 if non adaptive part
pascal@12756	3686 of start state comes
pascal@12756	3687 first 0 if that part
pascal@12756	3688 comes last */
pascal@12756	3689 ){
pascal@12756	3690 float reverseDecresidual[BLOCKL_MAX], mem[CB_MEML];
pascal@12756	3691 int k, meml_gotten, Nfor, Nback, i;
pascal@12756	3692 int diff, start_pos;
pascal@12756	3693 int subcount, subframe;
pascal@12756	3694
pascal@12756	3695
pascal@12756	3696
pascal@12756	3697
pascal@12756	3698 Andersen, et al. Experimental [Page 66]
pascal@12756	3699
pascal@12756	3700 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3701
pascal@12756	3702
pascal@12756	3703 diff = STATE_LEN - iLBCdec_inst->state_short_len;
pascal@12756	3704
pascal@12756	3705 if (state_first == 1) {
pascal@12756	3706 start_pos = (start-1)*SUBL;
pascal@12756	3707 } else {
pascal@12756	3708 start_pos = (start-1)*SUBL + diff;
pascal@12756	3709 }
pascal@12756	3710
pascal@12756	3711 /* decode scalar part of start state */
pascal@12756	3712
pascal@12756	3713 StateConstructW(idxForMax, idxVec,
pascal@12756	3714 &syntdenum[(start-1)*(LPC_FILTERORDER+1)],
pascal@12756	3715 &decresidual[start_pos], iLBCdec_inst->state_short_len);
pascal@12756	3716
pascal@12756	3717
pascal@12756	3718 if (state_first) { /* put adaptive part in the end */
pascal@12756	3719
pascal@12756	3720 /* setup memory */
pascal@12756	3721
pascal@12756	3722 memset(mem, 0,
pascal@12756	3723 (CB_MEML-iLBCdec_inst->state_short_len)*sizeof(float));
pascal@12756	3724 memcpy(mem+CB_MEML-iLBCdec_inst->state_short_len,
pascal@12756	3725 decresidual+start_pos,
pascal@12756	3726 iLBCdec_inst->state_short_len*sizeof(float));
pascal@12756	3727
pascal@12756	3728 /* construct decoded vector */
pascal@12756	3729
pascal@12756	3730 iCBConstruct(
pascal@12756	3731 &decresidual[start_pos+iLBCdec_inst->state_short_len],
pascal@12756	3732 extra_cb_index, extra_gain_index, mem+CB_MEML-stMemLTbl,
pascal@12756	3733 stMemLTbl, diff, CB_NSTAGES);
pascal@12756	3734
pascal@12756	3735 }
pascal@12756	3736 else {/* put adaptive part in the beginning */
pascal@12756	3737
pascal@12756	3738 /* create reversed vectors for prediction */
pascal@12756	3739
pascal@12756	3740 for (k=0; k<diff; k++) {
pascal@12756	3741 reverseDecresidual[k] =
pascal@12756	3742 decresidual[(start+1)*SUBL-1-
pascal@12756	3743 (k+iLBCdec_inst->state_short_len)];
pascal@12756	3744 }
pascal@12756	3745
pascal@12756	3746 /* setup memory */
pascal@12756	3747
pascal@12756	3748 meml_gotten = iLBCdec_inst->state_short_len;
pascal@12756	3749 for (k=0; k<meml_gotten; k++){
pascal@12756	3750 mem[CB_MEML-1-k] = decresidual[start_pos + k];
pascal@12756	3751
pascal@12756	3752
pascal@12756	3753
pascal@12756	3754 Andersen, et al. Experimental [Page 67]
pascal@12756	3755
pascal@12756	3756 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3757
pascal@12756	3758
pascal@12756	3759 }
pascal@12756	3760 memset(mem, 0, (CB_MEML-k)*sizeof(float));
pascal@12756	3761
pascal@12756	3762 /* construct decoded vector */
pascal@12756	3763
pascal@12756	3764 iCBConstruct(reverseDecresidual, extra_cb_index,
pascal@12756	3765 extra_gain_index, mem+CB_MEML-stMemLTbl, stMemLTbl,
pascal@12756	3766 diff, CB_NSTAGES);
pascal@12756	3767
pascal@12756	3768 /* get decoded residual from reversed vector */
pascal@12756	3769
pascal@12756	3770 for (k=0; k<diff; k++) {
pascal@12756	3771 decresidual[start_pos-1-k] = reverseDecresidual[k];
pascal@12756	3772 }
pascal@12756	3773 }
pascal@12756	3774
pascal@12756	3775 /* counter for predicted sub-frames */
pascal@12756	3776
pascal@12756	3777 subcount=0;
pascal@12756	3778
pascal@12756	3779 /* forward prediction of sub-frames */
pascal@12756	3780
pascal@12756	3781 Nfor = iLBCdec_inst->nsub-start-1;
pascal@12756	3782
pascal@12756	3783 if ( Nfor > 0 ){
pascal@12756	3784
pascal@12756	3785 /* setup memory */
pascal@12756	3786
pascal@12756	3787 memset(mem, 0, (CB_MEML-STATE_LEN)*sizeof(float));
pascal@12756	3788 memcpy(mem+CB_MEML-STATE_LEN, decresidual+(start-1)*SUBL,
pascal@12756	3789 STATE_LEN*sizeof(float));
pascal@12756	3790
pascal@12756	3791 /* loop over sub-frames to encode */
pascal@12756	3792
pascal@12756	3793 for (subframe=0; subframe<Nfor; subframe++) {
pascal@12756	3794
pascal@12756	3795 /* construct decoded vector */
pascal@12756	3796
pascal@12756	3797 iCBConstruct(&decresidual[(start+1+subframe)*SUBL],
pascal@12756	3798 cb_index+subcount*CB_NSTAGES,
pascal@12756	3799 gain_index+subcount*CB_NSTAGES,
pascal@12756	3800 mem+CB_MEML-memLfTbl[subcount],
pascal@12756	3801 memLfTbl[subcount], SUBL, CB_NSTAGES);
pascal@12756	3802
pascal@12756	3803 /* update memory */
pascal@12756	3804
pascal@12756	3805 memcpy(mem, mem+SUBL, (CB_MEML-SUBL)*sizeof(float));
pascal@12756	3806 memcpy(mem+CB_MEML-SUBL,
pascal@12756	3807
pascal@12756	3808
pascal@12756	3809
pascal@12756	3810 Andersen, et al. Experimental [Page 68]
pascal@12756	3811
pascal@12756	3812 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3813
pascal@12756	3814
pascal@12756	3815 &decresidual[(start+1+subframe)*SUBL],
pascal@12756	3816 SUBL*sizeof(float));
pascal@12756	3817
pascal@12756	3818 subcount++;
pascal@12756	3819
pascal@12756	3820 }
pascal@12756	3821
pascal@12756	3822 }
pascal@12756	3823
pascal@12756	3824 /* backward prediction of sub-frames */
pascal@12756	3825
pascal@12756	3826 Nback = start-1;
pascal@12756	3827
pascal@12756	3828 if ( Nback > 0 ) {
pascal@12756	3829
pascal@12756	3830 /* setup memory */
pascal@12756	3831
pascal@12756	3832 meml_gotten = SUBL*(iLBCdec_inst->nsub+1-start);
pascal@12756	3833
pascal@12756	3834 if ( meml_gotten > CB_MEML ) {
pascal@12756	3835 meml_gotten=CB_MEML;
pascal@12756	3836 }
pascal@12756	3837 for (k=0; k<meml_gotten; k++) {
pascal@12756	3838 mem[CB_MEML-1-k] = decresidual[(start-1)*SUBL + k];
pascal@12756	3839 }
pascal@12756	3840 memset(mem, 0, (CB_MEML-k)*sizeof(float));
pascal@12756	3841
pascal@12756	3842 /* loop over subframes to decode */
pascal@12756	3843
pascal@12756	3844 for (subframe=0; subframe<Nback; subframe++) {
pascal@12756	3845
pascal@12756	3846 /* construct decoded vector */
pascal@12756	3847
pascal@12756	3848 iCBConstruct(&reverseDecresidual[subframe*SUBL],
pascal@12756	3849 cb_index+subcount*CB_NSTAGES,
pascal@12756	3850 gain_index+subcount*CB_NSTAGES,
pascal@12756	3851 mem+CB_MEML-memLfTbl[subcount], memLfTbl[subcount],
pascal@12756	3852 SUBL, CB_NSTAGES);
pascal@12756	3853
pascal@12756	3854 /* update memory */
pascal@12756	3855
pascal@12756	3856 memcpy(mem, mem+SUBL, (CB_MEML-SUBL)*sizeof(float));
pascal@12756	3857 memcpy(mem+CB_MEML-SUBL,
pascal@12756	3858 &reverseDecresidual[subframe*SUBL],
pascal@12756	3859 SUBL*sizeof(float));
pascal@12756	3860
pascal@12756	3861 subcount++;
pascal@12756	3862 }
pascal@12756	3863
pascal@12756	3864
pascal@12756	3865
pascal@12756	3866 Andersen, et al. Experimental [Page 69]
pascal@12756	3867
pascal@12756	3868 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3869
pascal@12756	3870
pascal@12756	3871 /* get decoded residual from reversed vector */
pascal@12756	3872
pascal@12756	3873 for (i=0; i<SUBL*Nback; i++)
pascal@12756	3874 decresidual[SUBL*Nback - i - 1] =
pascal@12756	3875 reverseDecresidual[i];
pascal@12756	3876 }
pascal@12756	3877 }
pascal@12756	3878
pascal@12756	3879 /----------------------------------------------------------------
pascal@12756	3880 * main decoder function
pascal@12756	3881 ---------------------------------------------------------------/
pascal@12756	3882
pascal@12756	3883 void iLBC_decode(
pascal@12756	3884 float decblock, / (o) decoded signal block */
pascal@12756	3885 unsigned char bytes, / (i) encoded signal bits */
pascal@12756	3886 iLBC_Dec_Inst_t iLBCdec_inst, / (i/o) the decoder state
pascal@12756	3887 structure */
pascal@12756	3888 int mode /* (i) 0: bad packet, PLC,
pascal@12756	3889 1: normal */
pascal@12756	3890 ){
pascal@12756	3891 float data[BLOCKL_MAX];
pascal@12756	3892 float lsfdeq[LPC_FILTERORDER*LPC_N_MAX];
pascal@12756	3893 float PLCresidual[BLOCKL_MAX], PLClpc[LPC_FILTERORDER + 1];
pascal@12756	3894 float zeros[BLOCKL_MAX], one[LPC_FILTERORDER + 1];
pascal@12756	3895 int k, i, start, idxForMax, pos, lastpart, ulp;
pascal@12756	3896 int lag, ilag;
pascal@12756	3897 float cc, maxcc;
pascal@12756	3898 int idxVec[STATE_LEN];
pascal@12756	3899 int check;
pascal@12756	3900 int gain_index[NASUB_MAX*CB_NSTAGES],
pascal@12756	3901 extra_gain_index[CB_NSTAGES];
pascal@12756	3902 int cb_index[CB_NSTAGES*NASUB_MAX], extra_cb_index[CB_NSTAGES];
pascal@12756	3903 int lsf_i[LSF_NSPLIT*LPC_N_MAX];
pascal@12756	3904 int state_first;
pascal@12756	3905 int last_bit;
pascal@12756	3906 unsigned char *pbytes;
pascal@12756	3907 float weightdenum[(LPC_FILTERORDER + 1)*NSUB_MAX];
pascal@12756	3908 int order_plus_one;
pascal@12756	3909 float syntdenum[NSUB_MAX*(LPC_FILTERORDER+1)];
pascal@12756	3910 float decresidual[BLOCKL_MAX];
pascal@12756	3911
pascal@12756	3912 if (mode>0) { /* the data are good */
pascal@12756	3913
pascal@12756	3914 /* decode data */
pascal@12756	3915
pascal@12756	3916 pbytes=bytes;
pascal@12756	3917 pos=0;
pascal@12756	3918
pascal@12756	3919
pascal@12756	3920
pascal@12756	3921
pascal@12756	3922 Andersen, et al. Experimental [Page 70]
pascal@12756	3923
pascal@12756	3924 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3925
pascal@12756	3926
pascal@12756	3927 /* Set everything to zero before decoding */
pascal@12756	3928
pascal@12756	3929 for (k=0; k<LSF_NSPLIT*LPC_N_MAX; k++) {
pascal@12756	3930 lsf_i[k]=0;
pascal@12756	3931 }
pascal@12756	3932 start=0;
pascal@12756	3933 state_first=0;
pascal@12756	3934 idxForMax=0;
pascal@12756	3935 for (k=0; k<iLBCdec_inst->state_short_len; k++) {
pascal@12756	3936 idxVec[k]=0;
pascal@12756	3937 }
pascal@12756	3938 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	3939 extra_cb_index[k]=0;
pascal@12756	3940 }
pascal@12756	3941 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	3942 extra_gain_index[k]=0;
pascal@12756	3943 }
pascal@12756	3944 for (i=0; i<iLBCdec_inst->nasub; i++) {
pascal@12756	3945 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	3946 cb_index[i*CB_NSTAGES+k]=0;
pascal@12756	3947 }
pascal@12756	3948 }
pascal@12756	3949 for (i=0; i<iLBCdec_inst->nasub; i++) {
pascal@12756	3950 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	3951 gain_index[i*CB_NSTAGES+k]=0;
pascal@12756	3952 }
pascal@12756	3953 }
pascal@12756	3954
pascal@12756	3955 /* loop over ULP classes */
pascal@12756	3956
pascal@12756	3957 for (ulp=0; ulp<3; ulp++) {
pascal@12756	3958
pascal@12756	3959 /* LSF */
pascal@12756	3960 for (k=0; k<LSF_NSPLIT*iLBCdec_inst->lpc_n; k++){
pascal@12756	3961 unpack( &pbytes, &lastpart,
pascal@12756	3962 iLBCdec_inst->ULP_inst->lsf_bits[k][ulp], &pos);
pascal@12756	3963 packcombine(&lsf_i[k], lastpart,
pascal@12756	3964 iLBCdec_inst->ULP_inst->lsf_bits[k][ulp]);
pascal@12756	3965 }
pascal@12756	3966
pascal@12756	3967 /* Start block info */
pascal@12756	3968
pascal@12756	3969 unpack( &pbytes, &lastpart,
pascal@12756	3970 iLBCdec_inst->ULP_inst->start_bits[ulp], &pos);
pascal@12756	3971 packcombine(&start, lastpart,
pascal@12756	3972 iLBCdec_inst->ULP_inst->start_bits[ulp]);
pascal@12756	3973
pascal@12756	3974 unpack( &pbytes, &lastpart,
pascal@12756	3975
pascal@12756	3976
pascal@12756	3977
pascal@12756	3978 Andersen, et al. Experimental [Page 71]
pascal@12756	3979
pascal@12756	3980 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	3981
pascal@12756	3982
pascal@12756	3983 iLBCdec_inst->ULP_inst->startfirst_bits[ulp], &pos);
pascal@12756	3984 packcombine(&state_first, lastpart,
pascal@12756	3985 iLBCdec_inst->ULP_inst->startfirst_bits[ulp]);
pascal@12756	3986
pascal@12756	3987 unpack( &pbytes, &lastpart,
pascal@12756	3988 iLBCdec_inst->ULP_inst->scale_bits[ulp], &pos);
pascal@12756	3989 packcombine(&idxForMax, lastpart,
pascal@12756	3990 iLBCdec_inst->ULP_inst->scale_bits[ulp]);
pascal@12756	3991
pascal@12756	3992 for (k=0; k<iLBCdec_inst->state_short_len; k++) {
pascal@12756	3993 unpack( &pbytes, &lastpart,
pascal@12756	3994 iLBCdec_inst->ULP_inst->state_bits[ulp], &pos);
pascal@12756	3995 packcombine(idxVec+k, lastpart,
pascal@12756	3996 iLBCdec_inst->ULP_inst->state_bits[ulp]);
pascal@12756	3997 }
pascal@12756	3998
pascal@12756	3999 /* 23/22 (20ms/30ms) sample block */
pascal@12756	4000
pascal@12756	4001 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	4002 unpack( &pbytes, &lastpart,
pascal@12756	4003 iLBCdec_inst->ULP_inst->extra_cb_index[k][ulp],
pascal@12756	4004 &pos);
pascal@12756	4005 packcombine(extra_cb_index+k, lastpart,
pascal@12756	4006 iLBCdec_inst->ULP_inst->extra_cb_index[k][ulp]);
pascal@12756	4007 }
pascal@12756	4008 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	4009 unpack( &pbytes, &lastpart,
pascal@12756	4010 iLBCdec_inst->ULP_inst->extra_cb_gain[k][ulp],
pascal@12756	4011 &pos);
pascal@12756	4012 packcombine(extra_gain_index+k, lastpart,
pascal@12756	4013 iLBCdec_inst->ULP_inst->extra_cb_gain[k][ulp]);
pascal@12756	4014 }
pascal@12756	4015
pascal@12756	4016 /* The two/four (20ms/30ms) 40 sample sub-blocks */
pascal@12756	4017
pascal@12756	4018 for (i=0; i<iLBCdec_inst->nasub; i++) {
pascal@12756	4019 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	4020 unpack( &pbytes, &lastpart,
pascal@12756	4021 iLBCdec_inst->ULP_inst->cb_index[i][k][ulp],
pascal@12756	4022 &pos);
pascal@12756	4023 packcombine(cb_index+i*CB_NSTAGES+k, lastpart,
pascal@12756	4024 iLBCdec_inst->ULP_inst->cb_index[i][k][ulp]);
pascal@12756	4025 }
pascal@12756	4026 }
pascal@12756	4027
pascal@12756	4028 for (i=0; i<iLBCdec_inst->nasub; i++) {
pascal@12756	4029 for (k=0; k<CB_NSTAGES; k++) {
pascal@12756	4030 unpack( &pbytes, &lastpart,
pascal@12756	4031
pascal@12756	4032
pascal@12756	4033
pascal@12756	4034 Andersen, et al. Experimental [Page 72]
pascal@12756	4035
pascal@12756	4036 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4037
pascal@12756	4038
pascal@12756	4039 iLBCdec_inst->ULP_inst->cb_gain[i][k][ulp],
pascal@12756	4040 &pos);
pascal@12756	4041 packcombine(gain_index+i*CB_NSTAGES+k, lastpart,
pascal@12756	4042 iLBCdec_inst->ULP_inst->cb_gain[i][k][ulp]);
pascal@12756	4043 }
pascal@12756	4044 }
pascal@12756	4045 }
pascal@12756	4046 /* Extract last bit. If it is 1 this indicates an
pascal@12756	4047 empty/lost frame */
pascal@12756	4048 unpack( &pbytes, &last_bit, 1, &pos);
pascal@12756	4049
pascal@12756	4050 /* Check for bit errors or empty/lost frames */
pascal@12756	4051 if (start<1)
pascal@12756	4052 mode = 0;
pascal@12756	4053 if (iLBCdec_inst->mode==20 && start>3)
pascal@12756	4054 mode = 0;
pascal@12756	4055 if (iLBCdec_inst->mode==30 && start>5)
pascal@12756	4056 mode = 0;
pascal@12756	4057 if (last_bit==1)
pascal@12756	4058 mode = 0;
pascal@12756	4059
pascal@12756	4060 if (mode==1) { /* No bit errors was detected,
pascal@12756	4061 continue decoding */
pascal@12756	4062
pascal@12756	4063 /* adjust index */
pascal@12756	4064 index_conv_dec(cb_index);
pascal@12756	4065
pascal@12756	4066 /* decode the lsf */
pascal@12756	4067
pascal@12756	4068 SimplelsfDEQ(lsfdeq, lsf_i, iLBCdec_inst->lpc_n);
pascal@12756	4069 check=LSF_check(lsfdeq, LPC_FILTERORDER,
pascal@12756	4070 iLBCdec_inst->lpc_n);
pascal@12756	4071 DecoderInterpolateLSF(syntdenum, weightdenum,
pascal@12756	4072 lsfdeq, LPC_FILTERORDER, iLBCdec_inst);
pascal@12756	4073
pascal@12756	4074 Decode(iLBCdec_inst, decresidual, start, idxForMax,
pascal@12756	4075 idxVec, syntdenum, cb_index, gain_index,
pascal@12756	4076 extra_cb_index, extra_gain_index,
pascal@12756	4077 state_first);
pascal@12756	4078
pascal@12756	4079 /* preparing the plc for a future loss! */
pascal@12756	4080
pascal@12756	4081 doThePLC(PLCresidual, PLClpc, 0, decresidual,
pascal@12756	4082 syntdenum +
pascal@12756	4083 (LPC_FILTERORDER + 1)*(iLBCdec_inst->nsub - 1),
pascal@12756	4084 (*iLBCdec_inst).last_lag, iLBCdec_inst);
pascal@12756	4085
pascal@12756	4086
pascal@12756	4087
pascal@12756	4088
pascal@12756	4089
pascal@12756	4090 Andersen, et al. Experimental [Page 73]
pascal@12756	4091
pascal@12756	4092 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4093
pascal@12756	4094
pascal@12756	4095 memcpy(decresidual, PLCresidual,
pascal@12756	4096 iLBCdec_inst->blockl*sizeof(float));
pascal@12756	4097 }
pascal@12756	4098
pascal@12756	4099 }
pascal@12756	4100
pascal@12756	4101 if (mode == 0) {
pascal@12756	4102 /* the data is bad (either a PLC call
pascal@12756	4103 * was made or a severe bit error was detected)
pascal@12756	4104 */
pascal@12756	4105
pascal@12756	4106 /* packet loss conceal */
pascal@12756	4107
pascal@12756	4108 memset(zeros, 0, BLOCKL_MAX*sizeof(float));
pascal@12756	4109
pascal@12756	4110 one[0] = 1;
pascal@12756	4111 memset(one+1, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	4112
pascal@12756	4113 start=0;
pascal@12756	4114
pascal@12756	4115 doThePLC(PLCresidual, PLClpc, 1, zeros, one,
pascal@12756	4116 (*iLBCdec_inst).last_lag, iLBCdec_inst);
pascal@12756	4117 memcpy(decresidual, PLCresidual,
pascal@12756	4118 iLBCdec_inst->blockl*sizeof(float));
pascal@12756	4119
pascal@12756	4120 order_plus_one = LPC_FILTERORDER + 1;
pascal@12756	4121 for (i = 0; i < iLBCdec_inst->nsub; i++) {
pascal@12756	4122 memcpy(syntdenum+(i*order_plus_one), PLClpc,
pascal@12756	4123 order_plus_one*sizeof(float));
pascal@12756	4124 }
pascal@12756	4125 }
pascal@12756	4126
pascal@12756	4127 if (iLBCdec_inst->use_enhancer == 1) {
pascal@12756	4128
pascal@12756	4129 /* post filtering */
pascal@12756	4130
pascal@12756	4131 iLBCdec_inst->last_lag =
pascal@12756	4132 enhancerInterface(data, decresidual, iLBCdec_inst);
pascal@12756	4133
pascal@12756	4134 /* synthesis filtering */
pascal@12756	4135
pascal@12756	4136 if (iLBCdec_inst->mode==20) {
pascal@12756	4137 /* Enhancer has 40 samples delay */
pascal@12756	4138 i=0;
pascal@12756	4139 syntFilter(data + i*SUBL,
pascal@12756	4140 iLBCdec_inst->old_syntdenum +
pascal@12756	4141 (i+iLBCdec_inst->nsub-1)*(LPC_FILTERORDER+1),
pascal@12756	4142 SUBL, iLBCdec_inst->syntMem);
pascal@12756	4143
pascal@12756	4144
pascal@12756	4145
pascal@12756	4146 Andersen, et al. Experimental [Page 74]
pascal@12756	4147
pascal@12756	4148 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4149
pascal@12756	4150
pascal@12756	4151 for (i=1; i < iLBCdec_inst->nsub; i++) {
pascal@12756	4152 syntFilter(data + i*SUBL,
pascal@12756	4153 syntdenum + (i-1)*(LPC_FILTERORDER+1),
pascal@12756	4154 SUBL, iLBCdec_inst->syntMem);
pascal@12756	4155 }
pascal@12756	4156 } else if (iLBCdec_inst->mode==30) {
pascal@12756	4157 /* Enhancer has 80 samples delay */
pascal@12756	4158 for (i=0; i < 2; i++) {
pascal@12756	4159 syntFilter(data + i*SUBL,
pascal@12756	4160 iLBCdec_inst->old_syntdenum +
pascal@12756	4161 (i+iLBCdec_inst->nsub-2)*(LPC_FILTERORDER+1),
pascal@12756	4162 SUBL, iLBCdec_inst->syntMem);
pascal@12756	4163 }
pascal@12756	4164 for (i=2; i < iLBCdec_inst->nsub; i++) {
pascal@12756	4165 syntFilter(data + i*SUBL,
pascal@12756	4166 syntdenum + (i-2)*(LPC_FILTERORDER+1), SUBL,
pascal@12756	4167 iLBCdec_inst->syntMem);
pascal@12756	4168 }
pascal@12756	4169 }
pascal@12756	4170
pascal@12756	4171 } else {
pascal@12756	4172
pascal@12756	4173 /* Find last lag */
pascal@12756	4174 lag = 20;
pascal@12756	4175 maxcc = xCorrCoef(&decresidual[BLOCKL_MAX-ENH_BLOCKL],
pascal@12756	4176 &decresidual[BLOCKL_MAX-ENH_BLOCKL-lag], ENH_BLOCKL);
pascal@12756	4177
pascal@12756	4178 for (ilag=21; ilag<120; ilag++) {
pascal@12756	4179 cc = xCorrCoef(&decresidual[BLOCKL_MAX-ENH_BLOCKL],
pascal@12756	4180 &decresidual[BLOCKL_MAX-ENH_BLOCKL-ilag],
pascal@12756	4181 ENH_BLOCKL);
pascal@12756	4182
pascal@12756	4183 if (cc > maxcc) {
pascal@12756	4184 maxcc = cc;
pascal@12756	4185 lag = ilag;
pascal@12756	4186 }
pascal@12756	4187 }
pascal@12756	4188 iLBCdec_inst->last_lag = lag;
pascal@12756	4189
pascal@12756	4190 /* copy data and run synthesis filter */
pascal@12756	4191
pascal@12756	4192 memcpy(data, decresidual,
pascal@12756	4193 iLBCdec_inst->blockl*sizeof(float));
pascal@12756	4194 for (i=0; i < iLBCdec_inst->nsub; i++) {
pascal@12756	4195 syntFilter(data + i*SUBL,
pascal@12756	4196 syntdenum + i*(LPC_FILTERORDER+1), SUBL,
pascal@12756	4197 iLBCdec_inst->syntMem);
pascal@12756	4198 }
pascal@12756	4199
pascal@12756	4200
pascal@12756	4201
pascal@12756	4202 Andersen, et al. Experimental [Page 75]
pascal@12756	4203
pascal@12756	4204 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4205
pascal@12756	4206
pascal@12756	4207 }
pascal@12756	4208
pascal@12756	4209 /* high pass filtering on output if desired, otherwise
pascal@12756	4210 copy to out */
pascal@12756	4211
pascal@12756	4212 hpOutput(data, iLBCdec_inst->blockl,
pascal@12756	4213 decblock,iLBCdec_inst->hpomem);
pascal@12756	4214
pascal@12756	4215 /* memcpy(decblock,data,iLBCdec_inst->blocklsizeof(float));/
pascal@12756	4216
pascal@12756	4217 memcpy(iLBCdec_inst->old_syntdenum, syntdenum,
pascal@12756	4218
pascal@12756	4219 iLBCdec_inst->nsub(LPC_FILTERORDER+1)sizeof(float));
pascal@12756	4220
pascal@12756	4221 iLBCdec_inst->prev_enh_pl=0;
pascal@12756	4222
pascal@12756	4223 if (mode==0) { /* PLC was used */
pascal@12756	4224 iLBCdec_inst->prev_enh_pl=1;
pascal@12756	4225 }
pascal@12756	4226 }
pascal@12756	4227
pascal@12756	4228 A.6. iLBC_define.h
pascal@12756	4229
pascal@12756	4230 /******************************************************************
pascal@12756	4231
pascal@12756	4232 iLBC Speech Coder ANSI-C Source Code
pascal@12756	4233
pascal@12756	4234 iLBC_define.h
pascal@12756	4235
pascal@12756	4236 Copyright (C) The Internet Society (2004).
pascal@12756	4237 All Rights Reserved.
pascal@12756	4238
pascal@12756	4239 ******************************************************************/
pascal@12756	4240 #include <string.h>
pascal@12756	4241
pascal@12756	4242 #ifndef __iLBC_ILBCDEFINE_H
pascal@12756	4243 #define __iLBC_ILBCDEFINE_H
pascal@12756	4244
pascal@12756	4245 /* general codec settings */
pascal@12756	4246
pascal@12756	4247 #define FS (float)8000.0
pascal@12756	4248 #define BLOCKL_20MS 160
pascal@12756	4249 #define BLOCKL_30MS 240
pascal@12756	4250 #define BLOCKL_MAX 240
pascal@12756	4251 #define NSUB_20MS 4
pascal@12756	4252 #define NSUB_30MS 6
pascal@12756	4253 #define NSUB_MAX 6
pascal@12756	4254 #define NASUB_20MS 2
pascal@12756	4255
pascal@12756	4256
pascal@12756	4257
pascal@12756	4258 Andersen, et al. Experimental [Page 76]
pascal@12756	4259
pascal@12756	4260 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4261
pascal@12756	4262
pascal@12756	4263 #define NASUB_30MS 4
pascal@12756	4264 #define NASUB_MAX 4
pascal@12756	4265 #define SUBL 40
pascal@12756	4266 #define STATE_LEN 80
pascal@12756	4267 #define STATE_SHORT_LEN_30MS 58
pascal@12756	4268 #define STATE_SHORT_LEN_20MS 57
pascal@12756	4269
pascal@12756	4270 /* LPC settings */
pascal@12756	4271
pascal@12756	4272 #define LPC_FILTERORDER 10
pascal@12756	4273 #define LPC_CHIRP_SYNTDENUM (float)0.9025
pascal@12756	4274 #define LPC_CHIRP_WEIGHTDENUM (float)0.4222
pascal@12756	4275 #define LPC_LOOKBACK 60
pascal@12756	4276 #define LPC_N_20MS 1
pascal@12756	4277 #define LPC_N_30MS 2
pascal@12756	4278 #define LPC_N_MAX 2
pascal@12756	4279 #define LPC_ASYMDIFF 20
pascal@12756	4280 #define LPC_BW (float)60.0
pascal@12756	4281 #define LPC_WN (float)1.0001
pascal@12756	4282 #define LSF_NSPLIT 3
pascal@12756	4283 #define LSF_NUMBER_OF_STEPS 4
pascal@12756	4284 #define LPC_HALFORDER (LPC_FILTERORDER/2)
pascal@12756	4285
pascal@12756	4286 /* cb settings */
pascal@12756	4287
pascal@12756	4288 #define CB_NSTAGES 3
pascal@12756	4289 #define CB_EXPAND 2
pascal@12756	4290 #define CB_MEML 147
pascal@12756	4291 #define CB_FILTERLEN 2*4
pascal@12756	4292 #define CB_HALFFILTERLEN 4
pascal@12756	4293 #define CB_RESRANGE 34
pascal@12756	4294 #define CB_MAXGAIN (float)1.3
pascal@12756	4295
pascal@12756	4296 /* enhancer */
pascal@12756	4297
pascal@12756	4298 #define ENH_BLOCKL 80 /* block length */
pascal@12756	4299 #define ENH_BLOCKL_HALF (ENH_BLOCKL/2)
pascal@12756	4300 #define ENH_HL 3 /* 2*ENH_HL+1 is number blocks
pascal@12756	4301 in said second sequence */
pascal@12756	4302 #define ENH_SLOP 2 /* max difference estimated and
pascal@12756	4303 correct pitch period */
pascal@12756	4304 #define ENH_PLOCSL 20 /* pitch-estimates and pitch-
pascal@12756	4305 locations buffer length */
pascal@12756	4306 #define ENH_OVERHANG 2
pascal@12756	4307 #define ENH_UPS0 4 /* upsampling rate */
pascal@12756	4308 #define ENH_FL0 3 /* 2*FLO+1 is the length of
pascal@12756	4309 each filter */
pascal@12756	4310 #define ENH_VECTL (ENH_BLOCKL+2*ENH_FL0)
pascal@12756	4311
pascal@12756	4312
pascal@12756	4313
pascal@12756	4314 Andersen, et al. Experimental [Page 77]
pascal@12756	4315
pascal@12756	4316 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4317
pascal@12756	4318
pascal@12756	4319 #define ENH_CORRDIM (2*ENH_SLOP+1)
pascal@12756	4320 #define ENH_NBLOCKS (BLOCKL_MAX/ENH_BLOCKL)
pascal@12756	4321 #define ENH_NBLOCKS_EXTRA 5
pascal@12756	4322 #define ENH_NBLOCKS_TOT 8 /* ENH_NBLOCKS +
pascal@12756	4323 ENH_NBLOCKS_EXTRA */
pascal@12756	4324 #define ENH_BUFL (ENH_NBLOCKS_TOT)*ENH_BLOCKL
pascal@12756	4325 #define ENH_ALPHA0 (float)0.05
pascal@12756	4326
pascal@12756	4327 /* Down sampling */
pascal@12756	4328
pascal@12756	4329 #define FILTERORDER_DS 7
pascal@12756	4330 #define DELAY_DS 3
pascal@12756	4331 #define FACTOR_DS 2
pascal@12756	4332
pascal@12756	4333 /* bit stream defs */
pascal@12756	4334
pascal@12756	4335 #define NO_OF_BYTES_20MS 38
pascal@12756	4336 #define NO_OF_BYTES_30MS 50
pascal@12756	4337 #define NO_OF_WORDS_20MS 19
pascal@12756	4338 #define NO_OF_WORDS_30MS 25
pascal@12756	4339 #define STATE_BITS 3
pascal@12756	4340 #define BYTE_LEN 8
pascal@12756	4341 #define ULP_CLASSES 3
pascal@12756	4342
pascal@12756	4343 /* help parameters */
pascal@12756	4344
pascal@12756	4345 #define FLOAT_MAX (float)1.0e37
pascal@12756	4346 #define EPS (float)2.220446049250313e-016
pascal@12756	4347 #define PI (float)3.14159265358979323846
pascal@12756	4348 #define MIN_SAMPLE -32768
pascal@12756	4349 #define MAX_SAMPLE 32767
pascal@12756	4350 #define TWO_PI (float)6.283185307
pascal@12756	4351 #define PI2 (float)0.159154943
pascal@12756	4352
pascal@12756	4353 /* type definition encoder instance */
pascal@12756	4354 typedef struct iLBC_ULP_Inst_t_ {
pascal@12756	4355 int lsf_bits[6][ULP_CLASSES+2];
pascal@12756	4356 int start_bits[ULP_CLASSES+2];
pascal@12756	4357 int startfirst_bits[ULP_CLASSES+2];
pascal@12756	4358 int scale_bits[ULP_CLASSES+2];
pascal@12756	4359 int state_bits[ULP_CLASSES+2];
pascal@12756	4360 int extra_cb_index[CB_NSTAGES][ULP_CLASSES+2];
pascal@12756	4361 int extra_cb_gain[CB_NSTAGES][ULP_CLASSES+2];
pascal@12756	4362 int cb_index[NSUB_MAX][CB_NSTAGES][ULP_CLASSES+2];
pascal@12756	4363 int cb_gain[NSUB_MAX][CB_NSTAGES][ULP_CLASSES+2];
pascal@12756	4364 } iLBC_ULP_Inst_t;
pascal@12756	4365
pascal@12756	4366 /* type definition encoder instance */
pascal@12756	4367
pascal@12756	4368
pascal@12756	4369
pascal@12756	4370 Andersen, et al. Experimental [Page 78]
pascal@12756	4371
pascal@12756	4372 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4373
pascal@12756	4374
pascal@12756	4375 typedef struct iLBC_Enc_Inst_t_ {
pascal@12756	4376
pascal@12756	4377 /* flag for frame size mode */
pascal@12756	4378 int mode;
pascal@12756	4379
pascal@12756	4380 /* basic parameters for different frame sizes */
pascal@12756	4381 int blockl;
pascal@12756	4382 int nsub;
pascal@12756	4383 int nasub;
pascal@12756	4384 int no_of_bytes, no_of_words;
pascal@12756	4385 int lpc_n;
pascal@12756	4386 int state_short_len;
pascal@12756	4387 const iLBC_ULP_Inst_t *ULP_inst;
pascal@12756	4388
pascal@12756	4389 /* analysis filter state */
pascal@12756	4390 float anaMem[LPC_FILTERORDER];
pascal@12756	4391
pascal@12756	4392 /* old lsf parameters for interpolation */
pascal@12756	4393 float lsfold[LPC_FILTERORDER];
pascal@12756	4394 float lsfdeqold[LPC_FILTERORDER];
pascal@12756	4395
pascal@12756	4396 /* signal buffer for LP analysis */
pascal@12756	4397 float lpc_buffer[LPC_LOOKBACK + BLOCKL_MAX];
pascal@12756	4398
pascal@12756	4399 /* state of input HP filter */
pascal@12756	4400 float hpimem[4];
pascal@12756	4401
pascal@12756	4402 } iLBC_Enc_Inst_t;
pascal@12756	4403
pascal@12756	4404 /* type definition decoder instance */
pascal@12756	4405 typedef struct iLBC_Dec_Inst_t_ {
pascal@12756	4406
pascal@12756	4407 /* flag for frame size mode */
pascal@12756	4408 int mode;
pascal@12756	4409
pascal@12756	4410 /* basic parameters for different frame sizes */
pascal@12756	4411 int blockl;
pascal@12756	4412 int nsub;
pascal@12756	4413 int nasub;
pascal@12756	4414 int no_of_bytes, no_of_words;
pascal@12756	4415 int lpc_n;
pascal@12756	4416 int state_short_len;
pascal@12756	4417 const iLBC_ULP_Inst_t *ULP_inst;
pascal@12756	4418
pascal@12756	4419 /* synthesis filter state */
pascal@12756	4420 float syntMem[LPC_FILTERORDER];
pascal@12756	4421
pascal@12756	4422 /* old LSF for interpolation */
pascal@12756	4423
pascal@12756	4424
pascal@12756	4425
pascal@12756	4426 Andersen, et al. Experimental [Page 79]
pascal@12756	4427
pascal@12756	4428 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4429
pascal@12756	4430
pascal@12756	4431 float lsfdeqold[LPC_FILTERORDER];
pascal@12756	4432
pascal@12756	4433 /* pitch lag estimated in enhancer and used in PLC */
pascal@12756	4434 int last_lag;
pascal@12756	4435
pascal@12756	4436 /* PLC state information */
pascal@12756	4437 int prevLag, consPLICount, prevPLI, prev_enh_pl;
pascal@12756	4438 float prevLpc[LPC_FILTERORDER+1];
pascal@12756	4439 float prevResidual[NSUB_MAX*SUBL];
pascal@12756	4440 float per;
pascal@12756	4441 unsigned long seed;
pascal@12756	4442
pascal@12756	4443 /* previous synthesis filter parameters */
pascal@12756	4444 float old_syntdenum[(LPC_FILTERORDER + 1)*NSUB_MAX];
pascal@12756	4445
pascal@12756	4446 /* state of output HP filter */
pascal@12756	4447 float hpomem[4];
pascal@12756	4448
pascal@12756	4449 /* enhancer state information */
pascal@12756	4450 int use_enhancer;
pascal@12756	4451 float enh_buf[ENH_BUFL];
pascal@12756	4452 float enh_period[ENH_NBLOCKS_TOT];
pascal@12756	4453
pascal@12756	4454 } iLBC_Dec_Inst_t;
pascal@12756	4455
pascal@12756	4456 #endif
pascal@12756	4457
pascal@12756	4458 A.7. constants.h
pascal@12756	4459
pascal@12756	4460 /******************************************************************
pascal@12756	4461
pascal@12756	4462 iLBC Speech Coder ANSI-C Source Code
pascal@12756	4463
pascal@12756	4464 constants.h
pascal@12756	4465
pascal@12756	4466 Copyright (C) The Internet Society (2004).
pascal@12756	4467 All Rights Reserved.
pascal@12756	4468
pascal@12756	4469 ******************************************************************/
pascal@12756	4470
pascal@12756	4471 #ifndef __iLBC_CONSTANTS_H
pascal@12756	4472 #define __iLBC_CONSTANTS_H
pascal@12756	4473
pascal@12756	4474 #include "iLBC_define.h"
pascal@12756	4475
pascal@12756	4476
pascal@12756	4477 /* ULP bit allocation */
pascal@12756	4478
pascal@12756	4479
pascal@12756	4480
pascal@12756	4481
pascal@12756	4482 Andersen, et al. Experimental [Page 80]
pascal@12756	4483
pascal@12756	4484 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4485
pascal@12756	4486
pascal@12756	4487 extern const iLBC_ULP_Inst_t ULP_20msTbl;
pascal@12756	4488 extern const iLBC_ULP_Inst_t ULP_30msTbl;
pascal@12756	4489
pascal@12756	4490 /* high pass filters */
pascal@12756	4491
pascal@12756	4492 extern float hpi_zero_coefsTbl[];
pascal@12756	4493 extern float hpi_pole_coefsTbl[];
pascal@12756	4494 extern float hpo_zero_coefsTbl[];
pascal@12756	4495 extern float hpo_pole_coefsTbl[];
pascal@12756	4496
pascal@12756	4497 /* low pass filters */
pascal@12756	4498 extern float lpFilt_coefsTbl[];
pascal@12756	4499
pascal@12756	4500 /* LPC analysis and quantization */
pascal@12756	4501
pascal@12756	4502 extern float lpc_winTbl[];
pascal@12756	4503 extern float lpc_asymwinTbl[];
pascal@12756	4504 extern float lpc_lagwinTbl[];
pascal@12756	4505 extern float lsfCbTbl[];
pascal@12756	4506 extern float lsfmeanTbl[];
pascal@12756	4507 extern int dim_lsfCbTbl[];
pascal@12756	4508 extern int size_lsfCbTbl[];
pascal@12756	4509 extern float lsf_weightTbl_30ms[];
pascal@12756	4510 extern float lsf_weightTbl_20ms[];
pascal@12756	4511
pascal@12756	4512 /* state quantization tables */
pascal@12756	4513
pascal@12756	4514 extern float state_sq3Tbl[];
pascal@12756	4515 extern float state_frgqTbl[];
pascal@12756	4516
pascal@12756	4517 /* gain quantization tables */
pascal@12756	4518
pascal@12756	4519 extern float gain_sq3Tbl[];
pascal@12756	4520 extern float gain_sq4Tbl[];
pascal@12756	4521 extern float gain_sq5Tbl[];
pascal@12756	4522
pascal@12756	4523 /* adaptive codebook definitions */
pascal@12756	4524
pascal@12756	4525 extern int search_rangeTbl[5][CB_NSTAGES];
pascal@12756	4526 extern int memLfTbl[];
pascal@12756	4527 extern int stMemLTbl;
pascal@12756	4528 extern float cbfiltersTbl[CB_FILTERLEN];
pascal@12756	4529
pascal@12756	4530 /* enhancer definitions */
pascal@12756	4531
pascal@12756	4532 extern float polyphaserTbl[];
pascal@12756	4533 extern float enh_plocsTbl[];
pascal@12756	4534
pascal@12756	4535
pascal@12756	4536
pascal@12756	4537
pascal@12756	4538 Andersen, et al. Experimental [Page 81]
pascal@12756	4539
pascal@12756	4540 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4541
pascal@12756	4542
pascal@12756	4543 #endif
pascal@12756	4544
pascal@12756	4545 A.8. constants.c
pascal@12756	4546
pascal@12756	4547 /******************************************************************
pascal@12756	4548
pascal@12756	4549 iLBC Speech Coder ANSI-C Source Code
pascal@12756	4550
pascal@12756	4551 constants.c
pascal@12756	4552
pascal@12756	4553 Copyright (C) The Internet Society (2004).
pascal@12756	4554 All Rights Reserved.
pascal@12756	4555
pascal@12756	4556 ******************************************************************/
pascal@12756	4557
pascal@12756	4558 #include "iLBC_define.h"
pascal@12756	4559
pascal@12756	4560 /* ULP bit allocation */
pascal@12756	4561
pascal@12756	4562 /* 20 ms frame */
pascal@12756	4563
pascal@12756	4564 const iLBC_ULP_Inst_t ULP_20msTbl = {
pascal@12756	4565 /* LSF */
pascal@12756	4566 { {6,0,0,0,0}, {7,0,0,0,0}, {7,0,0,0,0},
pascal@12756	4567 {0,0,0,0,0}, {0,0,0,0,0}, {0,0,0,0,0}},
pascal@12756	4568 /* Start state location, gain and samples */
pascal@12756	4569 {2,0,0,0,0},
pascal@12756	4570 {1,0,0,0,0},
pascal@12756	4571 {6,0,0,0,0},
pascal@12756	4572 {0,1,2,0,0},
pascal@12756	4573 /* extra CB index and extra CB gain */
pascal@12756	4574 {{6,0,1,0,0}, {0,0,7,0,0}, {0,0,7,0,0}},
pascal@12756	4575 {{2,0,3,0,0}, {1,1,2,0,0}, {0,0,3,0,0}},
pascal@12756	4576 /* CB index and CB gain */
pascal@12756	4577 { {{7,0,1,0,0}, {0,0,7,0,0}, {0,0,7,0,0}},
pascal@12756	4578 {{0,0,8,0,0}, {0,0,8,0,0}, {0,0,8,0,0}},
pascal@12756	4579 {{0,0,0,0,0}, {0,0,0,0,0}, {0,0,0,0,0}},
pascal@12756	4580 {{0,0,0,0,0}, {0,0,0,0,0}, {0,0,0,0,0}}},
pascal@12756	4581 { {{1,2,2,0,0}, {1,1,2,0,0}, {0,0,3,0,0}},
pascal@12756	4582 {{1,1,3,0,0}, {0,2,2,0,0}, {0,0,3,0,0}},
pascal@12756	4583 {{0,0,0,0,0}, {0,0,0,0,0}, {0,0,0,0,0}},
pascal@12756	4584 {{0,0,0,0,0}, {0,0,0,0,0}, {0,0,0,0,0}}}
pascal@12756	4585 };
pascal@12756	4586
pascal@12756	4587 /* 30 ms frame */
pascal@12756	4588
pascal@12756	4589 const iLBC_ULP_Inst_t ULP_30msTbl = {
pascal@12756	4590 /* LSF */
pascal@12756	4591
pascal@12756	4592
pascal@12756	4593
pascal@12756	4594 Andersen, et al. Experimental [Page 82]
pascal@12756	4595
pascal@12756	4596 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4597
pascal@12756	4598
pascal@12756	4599 { {6,0,0,0,0}, {7,0,0,0,0}, {7,0,0,0,0},
pascal@12756	4600 {6,0,0,0,0}, {7,0,0,0,0}, {7,0,0,0,0}},
pascal@12756	4601 /* Start state location, gain and samples */
pascal@12756	4602 {3,0,0,0,0},
pascal@12756	4603 {1,0,0,0,0},
pascal@12756	4604 {6,0,0,0,0},
pascal@12756	4605 {0,1,2,0,0},
pascal@12756	4606 /* extra CB index and extra CB gain */
pascal@12756	4607 {{4,2,1,0,0}, {0,0,7,0,0}, {0,0,7,0,0}},
pascal@12756	4608 {{1,1,3,0,0}, {1,1,2,0,0}, {0,0,3,0,0}},
pascal@12756	4609 /* CB index and CB gain */
pascal@12756	4610 { {{6,1,1,0,0}, {0,0,7,0,0}, {0,0,7,0,0}},
pascal@12756	4611 {{0,7,1,0,0}, {0,0,8,0,0}, {0,0,8,0,0}},
pascal@12756	4612 {{0,7,1,0,0}, {0,0,8,0,0}, {0,0,8,0,0}},
pascal@12756	4613 {{0,7,1,0,0}, {0,0,8,0,0}, {0,0,8,0,0}}},
pascal@12756	4614 { {{1,2,2,0,0}, {1,2,1,0,0}, {0,0,3,0,0}},
pascal@12756	4615 {{0,2,3,0,0}, {0,2,2,0,0}, {0,0,3,0,0}},
pascal@12756	4616 {{0,1,4,0,0}, {0,1,3,0,0}, {0,0,3,0,0}},
pascal@12756	4617 {{0,1,4,0,0}, {0,1,3,0,0}, {0,0,3,0,0}}}
pascal@12756	4618 };
pascal@12756	4619
pascal@12756	4620 /* HP Filters */
pascal@12756	4621
pascal@12756	4622 float hpi_zero_coefsTbl[3] = {
pascal@12756	4623 (float)0.92727436, (float)-1.8544941, (float)0.92727436
pascal@12756	4624 };
pascal@12756	4625 float hpi_pole_coefsTbl[3] = {
pascal@12756	4626 (float)1.0, (float)-1.9059465, (float)0.9114024
pascal@12756	4627 };
pascal@12756	4628 float hpo_zero_coefsTbl[3] = {
pascal@12756	4629 (float)0.93980581, (float)-1.8795834, (float)0.93980581
pascal@12756	4630 };
pascal@12756	4631 float hpo_pole_coefsTbl[3] = {
pascal@12756	4632 (float)1.0, (float)-1.9330735, (float)0.93589199
pascal@12756	4633 };
pascal@12756	4634
pascal@12756	4635 /* LP Filter */
pascal@12756	4636
pascal@12756	4637 float lpFilt_coefsTbl[FILTERORDER_DS]={
pascal@12756	4638 (float)-0.066650, (float)0.125000, (float)0.316650,
pascal@12756	4639 (float)0.414063, (float)0.316650,
pascal@12756	4640 (float)0.125000, (float)-0.066650
pascal@12756	4641 };
pascal@12756	4642
pascal@12756	4643 /* State quantization tables */
pascal@12756	4644
pascal@12756	4645 float state_sq3Tbl[8] = {
pascal@12756	4646 (float)-3.719849, (float)-2.177490, (float)-1.130005,
pascal@12756	4647
pascal@12756	4648
pascal@12756	4649
pascal@12756	4650 Andersen, et al. Experimental [Page 83]
pascal@12756	4651
pascal@12756	4652 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4653
pascal@12756	4654
pascal@12756	4655 (float)-0.309692, (float)0.444214, (float)1.329712,
pascal@12756	4656 (float)2.436279, (float)3.983887
pascal@12756	4657 };
pascal@12756	4658
pascal@12756	4659 float state_frgqTbl[64] = {
pascal@12756	4660 (float)1.000085, (float)1.071695, (float)1.140395,
pascal@12756	4661 (float)1.206868, (float)1.277188, (float)1.351503,
pascal@12756	4662 (float)1.429380, (float)1.500727, (float)1.569049,
pascal@12756	4663 (float)1.639599, (float)1.707071, (float)1.781531,
pascal@12756	4664 (float)1.840799, (float)1.901550, (float)1.956695,
pascal@12756	4665 (float)2.006750, (float)2.055474, (float)2.102787,
pascal@12756	4666 (float)2.142819, (float)2.183592, (float)2.217962,
pascal@12756	4667 (float)2.257177, (float)2.295739, (float)2.332967,
pascal@12756	4668 (float)2.369248, (float)2.402792, (float)2.435080,
pascal@12756	4669 (float)2.468598, (float)2.503394, (float)2.539284,
pascal@12756	4670 (float)2.572944, (float)2.605036, (float)2.636331,
pascal@12756	4671 (float)2.668939, (float)2.698780, (float)2.729101,
pascal@12756	4672 (float)2.759786, (float)2.789834, (float)2.818679,
pascal@12756	4673 (float)2.848074, (float)2.877470, (float)2.906899,
pascal@12756	4674 (float)2.936655, (float)2.967804, (float)3.000115,
pascal@12756	4675 (float)3.033367, (float)3.066355, (float)3.104231,
pascal@12756	4676 (float)3.141499, (float)3.183012, (float)3.222952,
pascal@12756	4677 (float)3.265433, (float)3.308441, (float)3.350823,
pascal@12756	4678 (float)3.395275, (float)3.442793, (float)3.490801,
pascal@12756	4679 (float)3.542514, (float)3.604064, (float)3.666050,
pascal@12756	4680 (float)3.740994, (float)3.830749, (float)3.938770,
pascal@12756	4681 (float)4.101764
pascal@12756	4682 };
pascal@12756	4683
pascal@12756	4684 /* CB tables */
pascal@12756	4685
pascal@12756	4686 int search_rangeTbl[5][CB_NSTAGES]={{58,58,58}, {108,44,44},
pascal@12756	4687 {108,108,108}, {108,108,108}, {108,108,108}};
pascal@12756	4688 int stMemLTbl=85;
pascal@12756	4689 int memLfTbl[NASUB_MAX]={147,147,147,147};
pascal@12756	4690
pascal@12756	4691 /* expansion filter(s) */
pascal@12756	4692
pascal@12756	4693 float cbfiltersTbl[CB_FILTERLEN]={
pascal@12756	4694 (float)-0.034180, (float)0.108887, (float)-0.184326,
pascal@12756	4695 (float)0.806152, (float)0.713379, (float)-0.144043,
pascal@12756	4696 (float)0.083740, (float)-0.033691
pascal@12756	4697 };
pascal@12756	4698
pascal@12756	4699 /* Gain Quantization */
pascal@12756	4700
pascal@12756	4701 float gain_sq3Tbl[8]={
pascal@12756	4702 (float)-1.000000, (float)-0.659973, (float)-0.330017,
pascal@12756	4703
pascal@12756	4704
pascal@12756	4705
pascal@12756	4706 Andersen, et al. Experimental [Page 84]
pascal@12756	4707
pascal@12756	4708 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4709
pascal@12756	4710
pascal@12756	4711 (float)0.000000, (float)0.250000, (float)0.500000,
pascal@12756	4712 (float)0.750000, (float)1.00000};
pascal@12756	4713
pascal@12756	4714 float gain_sq4Tbl[16]={
pascal@12756	4715 (float)-1.049988, (float)-0.900024, (float)-0.750000,
pascal@12756	4716 (float)-0.599976, (float)-0.450012, (float)-0.299988,
pascal@12756	4717 (float)-0.150024, (float)0.000000, (float)0.150024,
pascal@12756	4718 (float)0.299988, (float)0.450012, (float)0.599976,
pascal@12756	4719 (float)0.750000, (float)0.900024, (float)1.049988,
pascal@12756	4720 (float)1.200012};
pascal@12756	4721
pascal@12756	4722 float gain_sq5Tbl[32]={
pascal@12756	4723 (float)0.037476, (float)0.075012, (float)0.112488,
pascal@12756	4724 (float)0.150024, (float)0.187500, (float)0.224976,
pascal@12756	4725 (float)0.262512, (float)0.299988, (float)0.337524,
pascal@12756	4726 (float)0.375000, (float)0.412476, (float)0.450012,
pascal@12756	4727 (float)0.487488, (float)0.525024, (float)0.562500,
pascal@12756	4728 (float)0.599976, (float)0.637512, (float)0.674988,
pascal@12756	4729 (float)0.712524, (float)0.750000, (float)0.787476,
pascal@12756	4730 (float)0.825012, (float)0.862488, (float)0.900024,
pascal@12756	4731 (float)0.937500, (float)0.974976, (float)1.012512,
pascal@12756	4732 (float)1.049988, (float)1.087524, (float)1.125000,
pascal@12756	4733 (float)1.162476, (float)1.200012};
pascal@12756	4734
pascal@12756	4735 /* Enhancer - Upsamling a factor 4 (ENH_UPS0 = 4) */
pascal@12756	4736 float polyphaserTbl[ENH_UPS0(2ENH_FL0+1)]={
pascal@12756	4737 (float)0.000000, (float)0.000000, (float)0.000000,
pascal@12756	4738 (float)1.000000,
pascal@12756	4739 (float)0.000000, (float)0.000000, (float)0.000000,
pascal@12756	4740 (float)0.015625, (float)-0.076904, (float)0.288330,
pascal@12756	4741 (float)0.862061,
pascal@12756	4742 (float)-0.106445, (float)0.018799, (float)-0.015625,
pascal@12756	4743 (float)0.023682, (float)-0.124268, (float)0.601563,
pascal@12756	4744 (float)0.601563,
pascal@12756	4745 (float)-0.124268, (float)0.023682, (float)-0.023682,
pascal@12756	4746 (float)0.018799, (float)-0.106445, (float)0.862061,
pascal@12756	4747 (float)0.288330,
pascal@12756	4748 (float)-0.076904, (float)0.015625, (float)-0.018799};
pascal@12756	4749
pascal@12756	4750 float enh_plocsTbl[ENH_NBLOCKS_TOT] = {(float)40.0, (float)120.0,
pascal@12756	4751 (float)200.0, (float)280.0, (float)360.0,
pascal@12756	4752 (float)440.0, (float)520.0, (float)600.0};
pascal@12756	4753
pascal@12756	4754 /* LPC analysis and quantization */
pascal@12756	4755
pascal@12756	4756 int dim_lsfCbTbl[LSF_NSPLIT] = {3, 3, 4};
pascal@12756	4757 int size_lsfCbTbl[LSF_NSPLIT] = {64,128,128};
pascal@12756	4758
pascal@12756	4759
pascal@12756	4760
pascal@12756	4761
pascal@12756	4762 Andersen, et al. Experimental [Page 85]
pascal@12756	4763
pascal@12756	4764 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4765
pascal@12756	4766
pascal@12756	4767 float lsfmeanTbl[LPC_FILTERORDER] = {
pascal@12756	4768 (float)0.281738, (float)0.445801, (float)0.663330,
pascal@12756	4769 (float)0.962524, (float)1.251831, (float)1.533081,
pascal@12756	4770 (float)1.850586, (float)2.137817, (float)2.481445,
pascal@12756	4771 (float)2.777344};
pascal@12756	4772
pascal@12756	4773 float lsf_weightTbl_30ms[6] = {(float)(1.0/2.0), (float)1.0,
pascal@12756	4774 (float)(2.0/3.0),
pascal@12756	4775 (float)(1.0/3.0), (float)0.0, (float)0.0};
pascal@12756	4776
pascal@12756	4777 float lsf_weightTbl_20ms[4] = {(float)(3.0/4.0), (float)(2.0/4.0),
pascal@12756	4778 (float)(1.0/4.0), (float)(0.0)};
pascal@12756	4779
pascal@12756	4780 /* Hanning LPC window */
pascal@12756	4781 float lpc_winTbl[BLOCKL_MAX]={
pascal@12756	4782 (float)0.000183, (float)0.000671, (float)0.001526,
pascal@12756	4783 (float)0.002716, (float)0.004242, (float)0.006104,
pascal@12756	4784 (float)0.008301, (float)0.010834, (float)0.013702,
pascal@12756	4785 (float)0.016907, (float)0.020416, (float)0.024261,
pascal@12756	4786 (float)0.028442, (float)0.032928, (float)0.037750,
pascal@12756	4787 (float)0.042877, (float)0.048309, (float)0.054047,
pascal@12756	4788 (float)0.060089, (float)0.066437, (float)0.073090,
pascal@12756	4789 (float)0.080017, (float)0.087219, (float)0.094727,
pascal@12756	4790 (float)0.102509, (float)0.110535, (float)0.118835,
pascal@12756	4791 (float)0.127411, (float)0.136230, (float)0.145294,
pascal@12756	4792 (float)0.154602, (float)0.164154, (float)0.173920,
pascal@12756	4793 (float)0.183899, (float)0.194122, (float)0.204529,
pascal@12756	4794 (float)0.215149, (float)0.225952, (float)0.236938,
pascal@12756	4795 (float)0.248108, (float)0.259460, (float)0.270966,
pascal@12756	4796 (float)0.282654, (float)0.294464, (float)0.306396,
pascal@12756	4797 (float)0.318481, (float)0.330688, (float)0.343018,
pascal@12756	4798 (float)0.355438, (float)0.367981, (float)0.380585,
pascal@12756	4799 (float)0.393280, (float)0.406067, (float)0.418884,
pascal@12756	4800 (float)0.431763, (float)0.444702, (float)0.457672,
pascal@12756	4801 (float)0.470673, (float)0.483704, (float)0.496735,
pascal@12756	4802 (float)0.509766, (float)0.522797, (float)0.535828,
pascal@12756	4803 (float)0.548798, (float)0.561768, (float)0.574677,
pascal@12756	4804 (float)0.587524, (float)0.600342, (float)0.613068,
pascal@12756	4805 (float)0.625732, (float)0.638306, (float)0.650787,
pascal@12756	4806 (float)0.663147, (float)0.675415, (float)0.687561,
pascal@12756	4807 (float)0.699585, (float)0.711487, (float)0.723206,
pascal@12756	4808 (float)0.734802, (float)0.746216, (float)0.757477,
pascal@12756	4809 (float)0.768585, (float)0.779480, (float)0.790192,
pascal@12756	4810 (float)0.800720, (float)0.811005, (float)0.821106,
pascal@12756	4811 (float)0.830994, (float)0.840668, (float)0.850067,
pascal@12756	4812 (float)0.859253, (float)0.868225, (float)0.876892,
pascal@12756	4813 (float)0.885345, (float)0.893524, (float)0.901428,
pascal@12756	4814 (float)0.909058, (float)0.916412, (float)0.923492,
pascal@12756	4815
pascal@12756	4816
pascal@12756	4817
pascal@12756	4818 Andersen, et al. Experimental [Page 86]
pascal@12756	4819
pascal@12756	4820 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4821
pascal@12756	4822
pascal@12756	4823 (float)0.930267, (float)0.936768, (float)0.942963,
pascal@12756	4824 (float)0.948853, (float)0.954437, (float)0.959717,
pascal@12756	4825 (float)0.964691, (float)0.969360, (float)0.973694,
pascal@12756	4826 (float)0.977692, (float)0.981384, (float)0.984741,
pascal@12756	4827 (float)0.987762, (float)0.990479, (float)0.992828,
pascal@12756	4828 (float)0.994873, (float)0.996552, (float)0.997925,
pascal@12756	4829 (float)0.998932, (float)0.999603, (float)0.999969,
pascal@12756	4830 (float)0.999969, (float)0.999603, (float)0.998932,
pascal@12756	4831 (float)0.997925, (float)0.996552, (float)0.994873,
pascal@12756	4832 (float)0.992828, (float)0.990479, (float)0.987762,
pascal@12756	4833 (float)0.984741, (float)0.981384, (float)0.977692,
pascal@12756	4834 (float)0.973694, (float)0.969360, (float)0.964691,
pascal@12756	4835 (float)0.959717, (float)0.954437, (float)0.948853,
pascal@12756	4836 (float)0.942963, (float)0.936768, (float)0.930267,
pascal@12756	4837 (float)0.923492, (float)0.916412, (float)0.909058,
pascal@12756	4838 (float)0.901428, (float)0.893524, (float)0.885345,
pascal@12756	4839 (float)0.876892, (float)0.868225, (float)0.859253,
pascal@12756	4840 (float)0.850067, (float)0.840668, (float)0.830994,
pascal@12756	4841 (float)0.821106, (float)0.811005, (float)0.800720,
pascal@12756	4842 (float)0.790192, (float)0.779480, (float)0.768585,
pascal@12756	4843 (float)0.757477, (float)0.746216, (float)0.734802,
pascal@12756	4844 (float)0.723206, (float)0.711487, (float)0.699585,
pascal@12756	4845 (float)0.687561, (float)0.675415, (float)0.663147,
pascal@12756	4846 (float)0.650787, (float)0.638306, (float)0.625732,
pascal@12756	4847 (float)0.613068, (float)0.600342, (float)0.587524,
pascal@12756	4848 (float)0.574677, (float)0.561768, (float)0.548798,
pascal@12756	4849 (float)0.535828, (float)0.522797, (float)0.509766,
pascal@12756	4850 (float)0.496735, (float)0.483704, (float)0.470673,
pascal@12756	4851 (float)0.457672, (float)0.444702, (float)0.431763,
pascal@12756	4852 (float)0.418884, (float)0.406067, (float)0.393280,
pascal@12756	4853 (float)0.380585, (float)0.367981, (float)0.355438,
pascal@12756	4854 (float)0.343018, (float)0.330688, (float)0.318481,
pascal@12756	4855 (float)0.306396, (float)0.294464, (float)0.282654,
pascal@12756	4856 (float)0.270966, (float)0.259460, (float)0.248108,
pascal@12756	4857 (float)0.236938, (float)0.225952, (float)0.215149,
pascal@12756	4858 (float)0.204529, (float)0.194122, (float)0.183899,
pascal@12756	4859 (float)0.173920, (float)0.164154, (float)0.154602,
pascal@12756	4860 (float)0.145294, (float)0.136230, (float)0.127411,
pascal@12756	4861 (float)0.118835, (float)0.110535, (float)0.102509,
pascal@12756	4862 (float)0.094727, (float)0.087219, (float)0.080017,
pascal@12756	4863 (float)0.073090, (float)0.066437, (float)0.060089,
pascal@12756	4864 (float)0.054047, (float)0.048309, (float)0.042877,
pascal@12756	4865 (float)0.037750, (float)0.032928, (float)0.028442,
pascal@12756	4866 (float)0.024261, (float)0.020416, (float)0.016907,
pascal@12756	4867 (float)0.013702, (float)0.010834, (float)0.008301,
pascal@12756	4868 (float)0.006104, (float)0.004242, (float)0.002716,
pascal@12756	4869 (float)0.001526, (float)0.000671, (float)0.000183
pascal@12756	4870 };
pascal@12756	4871
pascal@12756	4872
pascal@12756	4873
pascal@12756	4874 Andersen, et al. Experimental [Page 87]
pascal@12756	4875
pascal@12756	4876 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4877
pascal@12756	4878
pascal@12756	4879 /* Asymmetric LPC window */
pascal@12756	4880 float lpc_asymwinTbl[BLOCKL_MAX]={
pascal@12756	4881 (float)0.000061, (float)0.000214, (float)0.000458,
pascal@12756	4882 (float)0.000824, (float)0.001282, (float)0.001831,
pascal@12756	4883 (float)0.002472, (float)0.003235, (float)0.004120,
pascal@12756	4884 (float)0.005066, (float)0.006134, (float)0.007294,
pascal@12756	4885 (float)0.008545, (float)0.009918, (float)0.011383,
pascal@12756	4886 (float)0.012939, (float)0.014587, (float)0.016357,
pascal@12756	4887 (float)0.018219, (float)0.020172, (float)0.022217,
pascal@12756	4888 (float)0.024353, (float)0.026611, (float)0.028961,
pascal@12756	4889 (float)0.031372, (float)0.033905, (float)0.036530,
pascal@12756	4890 (float)0.039276, (float)0.042084, (float)0.044983,
pascal@12756	4891 (float)0.047974, (float)0.051086, (float)0.054260,
pascal@12756	4892 (float)0.057526, (float)0.060883, (float)0.064331,
pascal@12756	4893 (float)0.067871, (float)0.071503, (float)0.075226,
pascal@12756	4894 (float)0.079010, (float)0.082916, (float)0.086884,
pascal@12756	4895 (float)0.090942, (float)0.095062, (float)0.099304,
pascal@12756	4896 (float)0.103607, (float)0.107971, (float)0.112427,
pascal@12756	4897 (float)0.116974, (float)0.121582, (float)0.126282,
pascal@12756	4898 (float)0.131073, (float)0.135895, (float)0.140839,
pascal@12756	4899 (float)0.145813, (float)0.150879, (float)0.156006,
pascal@12756	4900 (float)0.161224, (float)0.166504, (float)0.171844,
pascal@12756	4901 (float)0.177246, (float)0.182709, (float)0.188263,
pascal@12756	4902 (float)0.193848, (float)0.199524, (float)0.205231,
pascal@12756	4903 (float)0.211029, (float)0.216858, (float)0.222778,
pascal@12756	4904 (float)0.228729, (float)0.234741, (float)0.240814,
pascal@12756	4905 (float)0.246918, (float)0.253082, (float)0.259308,
pascal@12756	4906 (float)0.265564, (float)0.271881, (float)0.278259,
pascal@12756	4907 (float)0.284668, (float)0.291107, (float)0.297607,
pascal@12756	4908 (float)0.304138, (float)0.310730, (float)0.317322,
pascal@12756	4909 (float)0.323975, (float)0.330658, (float)0.337372,
pascal@12756	4910 (float)0.344147, (float)0.350922, (float)0.357727,
pascal@12756	4911 (float)0.364594, (float)0.371460, (float)0.378357,
pascal@12756	4912 (float)0.385284, (float)0.392212, (float)0.399170,
pascal@12756	4913 (float)0.406158, (float)0.413177, (float)0.420197,
pascal@12756	4914 (float)0.427246, (float)0.434296, (float)0.441376,
pascal@12756	4915 (float)0.448456, (float)0.455536, (float)0.462646,
pascal@12756	4916 (float)0.469757, (float)0.476868, (float)0.483978,
pascal@12756	4917 (float)0.491089, (float)0.498230, (float)0.505341,
pascal@12756	4918 (float)0.512451, (float)0.519592, (float)0.526703,
pascal@12756	4919 (float)0.533813, (float)0.540924, (float)0.548004,
pascal@12756	4920 (float)0.555084, (float)0.562164, (float)0.569244,
pascal@12756	4921 (float)0.576294, (float)0.583313, (float)0.590332,
pascal@12756	4922 (float)0.597321, (float)0.604309, (float)0.611267,
pascal@12756	4923 (float)0.618195, (float)0.625092, (float)0.631989,
pascal@12756	4924 (float)0.638855, (float)0.645660, (float)0.652466,
pascal@12756	4925 (float)0.659241, (float)0.665985, (float)0.672668,
pascal@12756	4926 (float)0.679352, (float)0.685974, (float)0.692566,
pascal@12756	4927
pascal@12756	4928
pascal@12756	4929
pascal@12756	4930 Andersen, et al. Experimental [Page 88]
pascal@12756	4931
pascal@12756	4932 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4933
pascal@12756	4934
pascal@12756	4935 (float)0.699127, (float)0.705658, (float)0.712128,
pascal@12756	4936 (float)0.718536, (float)0.724945, (float)0.731262,
pascal@12756	4937 (float)0.737549, (float)0.743805, (float)0.750000,
pascal@12756	4938 (float)0.756134, (float)0.762238, (float)0.768280,
pascal@12756	4939 (float)0.774261, (float)0.780182, (float)0.786072,
pascal@12756	4940 (float)0.791870, (float)0.797638, (float)0.803314,
pascal@12756	4941 (float)0.808960, (float)0.814514, (float)0.820038,
pascal@12756	4942 (float)0.825470, (float)0.830841, (float)0.836151,
pascal@12756	4943 (float)0.841400, (float)0.846558, (float)0.851654,
pascal@12756	4944 (float)0.856689, (float)0.861633, (float)0.866516,
pascal@12756	4945 (float)0.871338, (float)0.876068, (float)0.880737,
pascal@12756	4946 (float)0.885315, (float)0.889801, (float)0.894226,
pascal@12756	4947 (float)0.898560, (float)0.902832, (float)0.907013,
pascal@12756	4948 (float)0.911102, (float)0.915100, (float)0.919037,
pascal@12756	4949 (float)0.922882, (float)0.926636, (float)0.930328,
pascal@12756	4950 (float)0.933899, (float)0.937408, (float)0.940796,
pascal@12756	4951 (float)0.944122, (float)0.947357, (float)0.950470,
pascal@12756	4952 (float)0.953522, (float)0.956482, (float)0.959351,
pascal@12756	4953 (float)0.962097, (float)0.964783, (float)0.967377,
pascal@12756	4954 (float)0.969849, (float)0.972229, (float)0.974518,
pascal@12756	4955 (float)0.976715, (float)0.978821, (float)0.980835,
pascal@12756	4956 (float)0.982727, (float)0.984528, (float)0.986237,
pascal@12756	4957 (float)0.987854, (float)0.989380, (float)0.990784,
pascal@12756	4958 (float)0.992096, (float)0.993317, (float)0.994415,
pascal@12756	4959 (float)0.995422, (float)0.996338, (float)0.997162,
pascal@12756	4960 (float)0.997864, (float)0.998474, (float)0.998962,
pascal@12756	4961 (float)0.999390, (float)0.999695, (float)0.999878,
pascal@12756	4962 (float)0.999969, (float)0.999969, (float)0.996918,
pascal@12756	4963 (float)0.987701, (float)0.972382, (float)0.951050,
pascal@12756	4964 (float)0.923889, (float)0.891022, (float)0.852631,
pascal@12756	4965 (float)0.809021, (float)0.760406, (float)0.707092,
pascal@12756	4966 (float)0.649445, (float)0.587799, (float)0.522491,
pascal@12756	4967 (float)0.453979, (float)0.382690, (float)0.309021,
pascal@12756	4968 (float)0.233459, (float)0.156433, (float)0.078461
pascal@12756	4969 };
pascal@12756	4970
pascal@12756	4971 /* Lag window for LPC */
pascal@12756	4972 float lpc_lagwinTbl[LPC_FILTERORDER + 1]={
pascal@12756	4973 (float)1.000100, (float)0.998890, (float)0.995569,
pascal@12756	4974 (float)0.990057, (float)0.982392,
pascal@12756	4975 (float)0.972623, (float)0.960816, (float)0.947047,
pascal@12756	4976 (float)0.931405, (float)0.913989, (float)0.894909};
pascal@12756	4977
pascal@12756	4978 /* LSF quantization*/
pascal@12756	4979 float lsfCbTbl[64 * 3 + 128 * 3 + 128 * 4] = {
pascal@12756	4980 (float)0.155396, (float)0.273193, (float)0.451172,
pascal@12756	4981 (float)0.390503, (float)0.648071, (float)1.002075,
pascal@12756	4982 (float)0.440186, (float)0.692261, (float)0.955688,
pascal@12756	4983
pascal@12756	4984
pascal@12756	4985
pascal@12756	4986 Andersen, et al. Experimental [Page 89]
pascal@12756	4987
pascal@12756	4988 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	4989
pascal@12756	4990
pascal@12756	4991 (float)0.343628, (float)0.642334, (float)1.071533,
pascal@12756	4992 (float)0.318359, (float)0.491577, (float)0.670532,
pascal@12756	4993 (float)0.193115, (float)0.375488, (float)0.725708,
pascal@12756	4994 (float)0.364136, (float)0.510376, (float)0.658691,
pascal@12756	4995 (float)0.297485, (float)0.527588, (float)0.842529,
pascal@12756	4996 (float)0.227173, (float)0.365967, (float)0.563110,
pascal@12756	4997 (float)0.244995, (float)0.396729, (float)0.636475,
pascal@12756	4998 (float)0.169434, (float)0.300171, (float)0.520264,
pascal@12756	4999 (float)0.312866, (float)0.464478, (float)0.643188,
pascal@12756	5000 (float)0.248535, (float)0.429932, (float)0.626099,
pascal@12756	5001 (float)0.236206, (float)0.491333, (float)0.817139,
pascal@12756	5002 (float)0.334961, (float)0.625122, (float)0.895752,
pascal@12756	5003 (float)0.343018, (float)0.518555, (float)0.698608,
pascal@12756	5004 (float)0.372803, (float)0.659790, (float)0.945435,
pascal@12756	5005 (float)0.176880, (float)0.316528, (float)0.581421,
pascal@12756	5006 (float)0.416382, (float)0.625977, (float)0.805176,
pascal@12756	5007 (float)0.303223, (float)0.568726, (float)0.915039,
pascal@12756	5008 (float)0.203613, (float)0.351440, (float)0.588135,
pascal@12756	5009 (float)0.221191, (float)0.375000, (float)0.614746,
pascal@12756	5010 (float)0.199951, (float)0.323364, (float)0.476074,
pascal@12756	5011 (float)0.300781, (float)0.433350, (float)0.566895,
pascal@12756	5012 (float)0.226196, (float)0.354004, (float)0.507568,
pascal@12756	5013 (float)0.300049, (float)0.508179, (float)0.711670,
pascal@12756	5014 (float)0.312012, (float)0.492676, (float)0.763428,
pascal@12756	5015 (float)0.329956, (float)0.541016, (float)0.795776,
pascal@12756	5016 (float)0.373779, (float)0.604614, (float)0.928833,
pascal@12756	5017 (float)0.210571, (float)0.452026, (float)0.755249,
pascal@12756	5018 (float)0.271118, (float)0.473267, (float)0.662476,
pascal@12756	5019 (float)0.285522, (float)0.436890, (float)0.634399,
pascal@12756	5020 (float)0.246704, (float)0.565552, (float)0.859009,
pascal@12756	5021 (float)0.270508, (float)0.406250, (float)0.553589,
pascal@12756	5022 (float)0.361450, (float)0.578491, (float)0.813843,
pascal@12756	5023 (float)0.342651, (float)0.482788, (float)0.622437,
pascal@12756	5024 (float)0.340332, (float)0.549438, (float)0.743164,
pascal@12756	5025 (float)0.200439, (float)0.336304, (float)0.540894,
pascal@12756	5026 (float)0.407837, (float)0.644775, (float)0.895142,
pascal@12756	5027 (float)0.294678, (float)0.454834, (float)0.699097,
pascal@12756	5028 (float)0.193115, (float)0.344482, (float)0.643188,
pascal@12756	5029 (float)0.275757, (float)0.420776, (float)0.598755,
pascal@12756	5030 (float)0.380493, (float)0.608643, (float)0.861084,
pascal@12756	5031 (float)0.222778, (float)0.426147, (float)0.676514,
pascal@12756	5032 (float)0.407471, (float)0.700195, (float)1.053101,
pascal@12756	5033 (float)0.218384, (float)0.377197, (float)0.669922,
pascal@12756	5034 (float)0.313232, (float)0.454102, (float)0.600952,
pascal@12756	5035 (float)0.347412, (float)0.571533, (float)0.874146,
pascal@12756	5036 (float)0.238037, (float)0.405396, (float)0.729492,
pascal@12756	5037 (float)0.223877, (float)0.412964, (float)0.822021,
pascal@12756	5038 (float)0.395264, (float)0.582153, (float)0.743896,
pascal@12756	5039
pascal@12756	5040
pascal@12756	5041
pascal@12756	5042 Andersen, et al. Experimental [Page 90]
pascal@12756	5043
pascal@12756	5044 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5045
pascal@12756	5046
pascal@12756	5047 (float)0.247925, (float)0.485596, (float)0.720581,
pascal@12756	5048 (float)0.229126, (float)0.496582, (float)0.907715,
pascal@12756	5049 (float)0.260132, (float)0.566895, (float)1.012695,
pascal@12756	5050 (float)0.337402, (float)0.611572, (float)0.978149,
pascal@12756	5051 (float)0.267822, (float)0.447632, (float)0.769287,
pascal@12756	5052 (float)0.250610, (float)0.381714, (float)0.530029,
pascal@12756	5053 (float)0.430054, (float)0.805054, (float)1.221924,
pascal@12756	5054 (float)0.382568, (float)0.544067, (float)0.701660,
pascal@12756	5055 (float)0.383545, (float)0.710327, (float)1.149170,
pascal@12756	5056 (float)0.271362, (float)0.529053, (float)0.775513,
pascal@12756	5057 (float)0.246826, (float)0.393555, (float)0.588623,
pascal@12756	5058 (float)0.266846, (float)0.422119, (float)0.676758,
pascal@12756	5059 (float)0.311523, (float)0.580688, (float)0.838623,
pascal@12756	5060 (float)1.331177, (float)1.576782, (float)1.779541,
pascal@12756	5061 (float)1.160034, (float)1.401978, (float)1.768188,
pascal@12756	5062 (float)1.161865, (float)1.525146, (float)1.715332,
pascal@12756	5063 (float)0.759521, (float)0.913940, (float)1.119873,
pascal@12756	5064 (float)0.947144, (float)1.121338, (float)1.282471,
pascal@12756	5065 (float)1.015015, (float)1.557007, (float)1.804932,
pascal@12756	5066 (float)1.172974, (float)1.402100, (float)1.692627,
pascal@12756	5067 (float)1.087524, (float)1.474243, (float)1.665405,
pascal@12756	5068 (float)0.899536, (float)1.105225, (float)1.406250,
pascal@12756	5069 (float)1.148438, (float)1.484741, (float)1.796265,
pascal@12756	5070 (float)0.785645, (float)1.209839, (float)1.567749,
pascal@12756	5071 (float)0.867798, (float)1.166504, (float)1.450684,
pascal@12756	5072 (float)0.922485, (float)1.229858, (float)1.420898,
pascal@12756	5073 (float)0.791260, (float)1.123291, (float)1.409546,
pascal@12756	5074 (float)0.788940, (float)0.966064, (float)1.340332,
pascal@12756	5075 (float)1.051147, (float)1.272827, (float)1.556641,
pascal@12756	5076 (float)0.866821, (float)1.181152, (float)1.538818,
pascal@12756	5077 (float)0.906738, (float)1.373535, (float)1.607910,
pascal@12756	5078 (float)1.244751, (float)1.581421, (float)1.933838,
pascal@12756	5079 (float)0.913940, (float)1.337280, (float)1.539673,
pascal@12756	5080 (float)0.680542, (float)0.959229, (float)1.662720,
pascal@12756	5081 (float)0.887207, (float)1.430542, (float)1.800781,
pascal@12756	5082 (float)0.912598, (float)1.433594, (float)1.683960,
pascal@12756	5083 (float)0.860474, (float)1.060303, (float)1.455322,
pascal@12756	5084 (float)1.005127, (float)1.381104, (float)1.706909,
pascal@12756	5085 (float)0.800781, (float)1.363892, (float)1.829102,
pascal@12756	5086 (float)0.781860, (float)1.124390, (float)1.505981,
pascal@12756	5087 (float)1.003662, (float)1.471436, (float)1.684692,
pascal@12756	5088 (float)0.981323, (float)1.309570, (float)1.618042,
pascal@12756	5089 (float)1.228760, (float)1.554321, (float)1.756470,
pascal@12756	5090 (float)0.734375, (float)0.895752, (float)1.225586,
pascal@12756	5091 (float)0.841797, (float)1.055664, (float)1.249268,
pascal@12756	5092 (float)0.920166, (float)1.119385, (float)1.486206,
pascal@12756	5093 (float)0.894409, (float)1.539063, (float)1.828979,
pascal@12756	5094 (float)1.283691, (float)1.543335, (float)1.858276,
pascal@12756	5095
pascal@12756	5096
pascal@12756	5097
pascal@12756	5098 Andersen, et al. Experimental [Page 91]
pascal@12756	5099
pascal@12756	5100 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5101
pascal@12756	5102
pascal@12756	5103 (float)0.676025, (float)0.933105, (float)1.490845,
pascal@12756	5104 (float)0.821289, (float)1.491821, (float)1.739868,
pascal@12756	5105 (float)0.923218, (float)1.144653, (float)1.580566,
pascal@12756	5106 (float)1.057251, (float)1.345581, (float)1.635864,
pascal@12756	5107 (float)0.888672, (float)1.074951, (float)1.353149,
pascal@12756	5108 (float)0.942749, (float)1.195435, (float)1.505493,
pascal@12756	5109 (float)1.492310, (float)1.788086, (float)2.039673,
pascal@12756	5110 (float)1.070313, (float)1.634399, (float)1.860962,
pascal@12756	5111 (float)1.253296, (float)1.488892, (float)1.686035,
pascal@12756	5112 (float)0.647095, (float)0.864014, (float)1.401855,
pascal@12756	5113 (float)0.866699, (float)1.254883, (float)1.453369,
pascal@12756	5114 (float)1.063965, (float)1.532593, (float)1.731323,
pascal@12756	5115 (float)1.167847, (float)1.521484, (float)1.884033,
pascal@12756	5116 (float)0.956055, (float)1.502075, (float)1.745605,
pascal@12756	5117 (float)0.928711, (float)1.288574, (float)1.479614,
pascal@12756	5118 (float)1.088013, (float)1.380737, (float)1.570801,
pascal@12756	5119 (float)0.905029, (float)1.186768, (float)1.371948,
pascal@12756	5120 (float)1.057861, (float)1.421021, (float)1.617432,
pascal@12756	5121 (float)1.108276, (float)1.312500, (float)1.501465,
pascal@12756	5122 (float)0.979492, (float)1.416992, (float)1.624268,
pascal@12756	5123 (float)1.276001, (float)1.661011, (float)2.007935,
pascal@12756	5124 (float)0.993042, (float)1.168579, (float)1.331665,
pascal@12756	5125 (float)0.778198, (float)0.944946, (float)1.235962,
pascal@12756	5126 (float)1.223755, (float)1.491333, (float)1.815674,
pascal@12756	5127 (float)0.852661, (float)1.350464, (float)1.722290,
pascal@12756	5128 (float)1.134766, (float)1.593140, (float)1.787354,
pascal@12756	5129 (float)1.051392, (float)1.339722, (float)1.531006,
pascal@12756	5130 (float)0.803589, (float)1.271240, (float)1.652100,
pascal@12756	5131 (float)0.755737, (float)1.143555, (float)1.639404,
pascal@12756	5132 (float)0.700928, (float)0.837280, (float)1.130371,
pascal@12756	5133 (float)0.942749, (float)1.197876, (float)1.669800,
pascal@12756	5134 (float)0.993286, (float)1.378296, (float)1.566528,
pascal@12756	5135 (float)0.801025, (float)1.095337, (float)1.298950,
pascal@12756	5136 (float)0.739990, (float)1.032959, (float)1.383667,
pascal@12756	5137 (float)0.845703, (float)1.072266, (float)1.543823,
pascal@12756	5138 (float)0.915649, (float)1.072266, (float)1.224487,
pascal@12756	5139 (float)1.021973, (float)1.226196, (float)1.481323,
pascal@12756	5140 (float)0.999878, (float)1.204102, (float)1.555908,
pascal@12756	5141 (float)0.722290, (float)0.913940, (float)1.340210,
pascal@12756	5142 (float)0.673340, (float)0.835938, (float)1.259521,
pascal@12756	5143 (float)0.832397, (float)1.208374, (float)1.394165,
pascal@12756	5144 (float)0.962158, (float)1.576172, (float)1.912842,
pascal@12756	5145 (float)1.166748, (float)1.370850, (float)1.556763,
pascal@12756	5146 (float)0.946289, (float)1.138550, (float)1.400391,
pascal@12756	5147 (float)1.035034, (float)1.218262, (float)1.386475,
pascal@12756	5148 (float)1.393799, (float)1.717773, (float)2.000244,
pascal@12756	5149 (float)0.972656, (float)1.260986, (float)1.760620,
pascal@12756	5150 (float)1.028198, (float)1.288452, (float)1.484619,
pascal@12756	5151
pascal@12756	5152
pascal@12756	5153
pascal@12756	5154 Andersen, et al. Experimental [Page 92]
pascal@12756	5155
pascal@12756	5156 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5157
pascal@12756	5158
pascal@12756	5159 (float)0.773560, (float)1.258057, (float)1.756714,
pascal@12756	5160 (float)1.080322, (float)1.328003, (float)1.742676,
pascal@12756	5161 (float)0.823975, (float)1.450806, (float)1.917725,
pascal@12756	5162 (float)0.859009, (float)1.016602, (float)1.191895,
pascal@12756	5163 (float)0.843994, (float)1.131104, (float)1.645020,
pascal@12756	5164 (float)1.189697, (float)1.702759, (float)1.894409,
pascal@12756	5165 (float)1.346680, (float)1.763184, (float)2.066040,
pascal@12756	5166 (float)0.980469, (float)1.253784, (float)1.441650,
pascal@12756	5167 (float)1.338135, (float)1.641968, (float)1.932739,
pascal@12756	5168 (float)1.223267, (float)1.424194, (float)1.626465,
pascal@12756	5169 (float)0.765747, (float)1.004150, (float)1.579102,
pascal@12756	5170 (float)1.042847, (float)1.269165, (float)1.647461,
pascal@12756	5171 (float)0.968750, (float)1.257568, (float)1.555786,
pascal@12756	5172 (float)0.826294, (float)0.993408, (float)1.275146,
pascal@12756	5173 (float)0.742310, (float)0.950439, (float)1.430542,
pascal@12756	5174 (float)1.054321, (float)1.439819, (float)1.828003,
pascal@12756	5175 (float)1.072998, (float)1.261719, (float)1.441895,
pascal@12756	5176 (float)0.859375, (float)1.036377, (float)1.314819,
pascal@12756	5177 (float)0.895752, (float)1.267212, (float)1.605591,
pascal@12756	5178 (float)0.805420, (float)0.962891, (float)1.142334,
pascal@12756	5179 (float)0.795654, (float)1.005493, (float)1.468506,
pascal@12756	5180 (float)1.105347, (float)1.313843, (float)1.584839,
pascal@12756	5181 (float)0.792236, (float)1.221802, (float)1.465698,
pascal@12756	5182 (float)1.170532, (float)1.467651, (float)1.664063,
pascal@12756	5183 (float)0.838257, (float)1.153198, (float)1.342163,
pascal@12756	5184 (float)0.968018, (float)1.198242, (float)1.391235,
pascal@12756	5185 (float)1.250122, (float)1.623535, (float)1.823608,
pascal@12756	5186 (float)0.711670, (float)1.058350, (float)1.512085,
pascal@12756	5187 (float)1.204834, (float)1.454468, (float)1.739136,
pascal@12756	5188 (float)1.137451, (float)1.421753, (float)1.620117,
pascal@12756	5189 (float)0.820435, (float)1.322754, (float)1.578247,
pascal@12756	5190 (float)0.798706, (float)1.005005, (float)1.213867,
pascal@12756	5191 (float)0.980713, (float)1.324951, (float)1.512939,
pascal@12756	5192 (float)1.112305, (float)1.438843, (float)1.735596,
pascal@12756	5193 (float)1.135498, (float)1.356689, (float)1.635742,
pascal@12756	5194 (float)1.101318, (float)1.387451, (float)1.686523,
pascal@12756	5195 (float)0.849854, (float)1.276978, (float)1.523438,
pascal@12756	5196 (float)1.377930, (float)1.627563, (float)1.858154,
pascal@12756	5197 (float)0.884888, (float)1.095459, (float)1.287476,
pascal@12756	5198 (float)1.289795, (float)1.505859, (float)1.756592,
pascal@12756	5199 (float)0.817505, (float)1.384155, (float)1.650513,
pascal@12756	5200 (float)1.446655, (float)1.702148, (float)1.931885,
pascal@12756	5201 (float)0.835815, (float)1.023071, (float)1.385376,
pascal@12756	5202 (float)0.916626, (float)1.139038, (float)1.335327,
pascal@12756	5203 (float)0.980103, (float)1.174072, (float)1.453735,
pascal@12756	5204 (float)1.705688, (float)2.153809, (float)2.398315, (float)2.743408,
pascal@12756	5205 (float)1.797119, (float)2.016846, (float)2.445679, (float)2.701904,
pascal@12756	5206 (float)1.990356, (float)2.219116, (float)2.576416, (float)2.813477,
pascal@12756	5207
pascal@12756	5208
pascal@12756	5209
pascal@12756	5210 Andersen, et al. Experimental [Page 93]
pascal@12756	5211
pascal@12756	5212 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5213
pascal@12756	5214
pascal@12756	5215 (float)1.849365, (float)2.190918, (float)2.611572, (float)2.835083,
pascal@12756	5216 (float)1.657959, (float)1.854370, (float)2.159058, (float)2.726196,
pascal@12756	5217 (float)1.437744, (float)1.897705, (float)2.253174, (float)2.655396,
pascal@12756	5218 (float)2.028687, (float)2.247314, (float)2.542358, (float)2.875854,
pascal@12756	5219 (float)1.736938, (float)1.922119, (float)2.185913, (float)2.743408,
pascal@12756	5220 (float)1.521606, (float)1.870972, (float)2.526855, (float)2.786987,
pascal@12756	5221 (float)1.841431, (float)2.050659, (float)2.463623, (float)2.857666,
pascal@12756	5222 (float)1.590088, (float)2.067261, (float)2.427979, (float)2.794434,
pascal@12756	5223 (float)1.746826, (float)2.057373, (float)2.320190, (float)2.800781,
pascal@12756	5224 (float)1.734619, (float)1.940552, (float)2.306030, (float)2.826416,
pascal@12756	5225 (float)1.786255, (float)2.204468, (float)2.457520, (float)2.795288,
pascal@12756	5226 (float)1.861084, (float)2.170532, (float)2.414551, (float)2.763672,
pascal@12756	5227 (float)2.001465, (float)2.307617, (float)2.552734, (float)2.811890,
pascal@12756	5228 (float)1.784424, (float)2.124146, (float)2.381592, (float)2.645508,
pascal@12756	5229 (float)1.888794, (float)2.135864, (float)2.418579, (float)2.861206,
pascal@12756	5230 (float)2.301147, (float)2.531250, (float)2.724976, (float)2.913086,
pascal@12756	5231 (float)1.837769, (float)2.051270, (float)2.261963, (float)2.553223,
pascal@12756	5232 (float)2.012939, (float)2.221191, (float)2.440186, (float)2.678101,
pascal@12756	5233 (float)1.429565, (float)1.858276, (float)2.582275, (float)2.845703,
pascal@12756	5234 (float)1.622803, (float)1.897705, (float)2.367310, (float)2.621094,
pascal@12756	5235 (float)1.581543, (float)1.960449, (float)2.515869, (float)2.736450,
pascal@12756	5236 (float)1.419434, (float)1.933960, (float)2.394653, (float)2.746704,
pascal@12756	5237 (float)1.721924, (float)2.059570, (float)2.421753, (float)2.769653,
pascal@12756	5238 (float)1.911011, (float)2.220703, (float)2.461060, (float)2.740723,
pascal@12756	5239 (float)1.581177, (float)1.860840, (float)2.516968, (float)2.874634,
pascal@12756	5240 (float)1.870361, (float)2.098755, (float)2.432373, (float)2.656494,
pascal@12756	5241 (float)2.059692, (float)2.279785, (float)2.495605, (float)2.729370,
pascal@12756	5242 (float)1.815674, (float)2.181519, (float)2.451538, (float)2.680542,
pascal@12756	5243 (float)1.407959, (float)1.768311, (float)2.343018, (float)2.668091,
pascal@12756	5244 (float)2.168701, (float)2.394653, (float)2.604736, (float)2.829346,
pascal@12756	5245 (float)1.636230, (float)1.865723, (float)2.329102, (float)2.824219,
pascal@12756	5246 (float)1.878906, (float)2.139526, (float)2.376709, (float)2.679810,
pascal@12756	5247 (float)1.765381, (float)1.971802, (float)2.195435, (float)2.586914,
pascal@12756	5248 (float)2.164795, (float)2.410889, (float)2.673706, (float)2.903198,
pascal@12756	5249 (float)2.071899, (float)2.331055, (float)2.645874, (float)2.907104,
pascal@12756	5250 (float)2.026001, (float)2.311523, (float)2.594849, (float)2.863892,
pascal@12756	5251 (float)1.948975, (float)2.180786, (float)2.514893, (float)2.797852,
pascal@12756	5252 (float)1.881836, (float)2.130859, (float)2.478149, (float)2.804199,
pascal@12756	5253 (float)2.238159, (float)2.452759, (float)2.652832, (float)2.868286,
pascal@12756	5254 (float)1.897949, (float)2.101685, (float)2.524292, (float)2.880127,
pascal@12756	5255 (float)1.856445, (float)2.074585, (float)2.541016, (float)2.791748,
pascal@12756	5256 (float)1.695557, (float)2.199097, (float)2.506226, (float)2.742676,
pascal@12756	5257 (float)1.612671, (float)1.877075, (float)2.435425, (float)2.732910,
pascal@12756	5258 (float)1.568848, (float)1.786499, (float)2.194580, (float)2.768555,
pascal@12756	5259 (float)1.953369, (float)2.164551, (float)2.486938, (float)2.874023,
pascal@12756	5260 (float)1.388306, (float)1.725342, (float)2.384521, (float)2.771851,
pascal@12756	5261 (float)2.115356, (float)2.337769, (float)2.592896, (float)2.864014,
pascal@12756	5262 (float)1.905762, (float)2.111328, (float)2.363525, (float)2.789307,
pascal@12756	5263
pascal@12756	5264
pascal@12756	5265
pascal@12756	5266 Andersen, et al. Experimental [Page 94]
pascal@12756	5267
pascal@12756	5268 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5269
pascal@12756	5270
pascal@12756	5271 (float)1.882568, (float)2.332031, (float)2.598267, (float)2.827637,
pascal@12756	5272 (float)1.683594, (float)2.088745, (float)2.361938, (float)2.608643,
pascal@12756	5273 (float)1.874023, (float)2.182129, (float)2.536133, (float)2.766968,
pascal@12756	5274 (float)1.861938, (float)2.070435, (float)2.309692, (float)2.700562,
pascal@12756	5275 (float)1.722168, (float)2.107422, (float)2.477295, (float)2.837646,
pascal@12756	5276 (float)1.926880, (float)2.184692, (float)2.442627, (float)2.663818,
pascal@12756	5277 (float)2.123901, (float)2.337280, (float)2.553101, (float)2.777466,
pascal@12756	5278 (float)1.588135, (float)1.911499, (float)2.212769, (float)2.543945,
pascal@12756	5279 (float)2.053955, (float)2.370850, (float)2.712158, (float)2.939941,
pascal@12756	5280 (float)2.210449, (float)2.519653, (float)2.770386, (float)2.958618,
pascal@12756	5281 (float)2.199463, (float)2.474731, (float)2.718262, (float)2.919922,
pascal@12756	5282 (float)1.960083, (float)2.175415, (float)2.608032, (float)2.888794,
pascal@12756	5283 (float)1.953735, (float)2.185181, (float)2.428223, (float)2.809570,
pascal@12756	5284 (float)1.615234, (float)2.036499, (float)2.576538, (float)2.834595,
pascal@12756	5285 (float)1.621094, (float)2.028198, (float)2.431030, (float)2.664673,
pascal@12756	5286 (float)1.824951, (float)2.267456, (float)2.514526, (float)2.747925,
pascal@12756	5287 (float)1.994263, (float)2.229126, (float)2.475220, (float)2.833984,
pascal@12756	5288 (float)1.746338, (float)2.011353, (float)2.588257, (float)2.826904,
pascal@12756	5289 (float)1.562866, (float)2.135986, (float)2.471680, (float)2.687256,
pascal@12756	5290 (float)1.748901, (float)2.083496, (float)2.460938, (float)2.686279,
pascal@12756	5291 (float)1.758057, (float)2.131470, (float)2.636597, (float)2.891602,
pascal@12756	5292 (float)2.071289, (float)2.299072, (float)2.550781, (float)2.814331,
pascal@12756	5293 (float)1.839600, (float)2.094360, (float)2.496460, (float)2.723999,
pascal@12756	5294 (float)1.882202, (float)2.088257, (float)2.636841, (float)2.923096,
pascal@12756	5295 (float)1.957886, (float)2.153198, (float)2.384399, (float)2.615234,
pascal@12756	5296 (float)1.992920, (float)2.351196, (float)2.654419, (float)2.889771,
pascal@12756	5297 (float)2.012817, (float)2.262451, (float)2.643799, (float)2.903076,
pascal@12756	5298 (float)2.025635, (float)2.254761, (float)2.508423, (float)2.784058,
pascal@12756	5299 (float)2.316040, (float)2.589355, (float)2.794189, (float)2.963623,
pascal@12756	5300 (float)1.741211, (float)2.279541, (float)2.578491, (float)2.816284,
pascal@12756	5301 (float)1.845337, (float)2.055786, (float)2.348511, (float)2.822021,
pascal@12756	5302 (float)1.679932, (float)1.926514, (float)2.499756, (float)2.835693,
pascal@12756	5303 (float)1.722534, (float)1.946899, (float)2.448486, (float)2.728760,
pascal@12756	5304 (float)1.829834, (float)2.043213, (float)2.580444, (float)2.867676,
pascal@12756	5305 (float)1.676636, (float)2.071655, (float)2.322510, (float)2.704834,
pascal@12756	5306 (float)1.791504, (float)2.113525, (float)2.469727, (float)2.784058,
pascal@12756	5307 (float)1.977051, (float)2.215088, (float)2.497437, (float)2.726929,
pascal@12756	5308 (float)1.800171, (float)2.106689, (float)2.357788, (float)2.738892,
pascal@12756	5309 (float)1.827759, (float)2.170166, (float)2.525879, (float)2.852417,
pascal@12756	5310 (float)1.918335, (float)2.132813, (float)2.488403, (float)2.728149,
pascal@12756	5311 (float)1.916748, (float)2.225098, (float)2.542603, (float)2.857666,
pascal@12756	5312 (float)1.761230, (float)1.976074, (float)2.507446, (float)2.884521,
pascal@12756	5313 (float)2.053711, (float)2.367432, (float)2.608032, (float)2.837646,
pascal@12756	5314 (float)1.595337, (float)2.000977, (float)2.307129, (float)2.578247,
pascal@12756	5315 (float)1.470581, (float)2.031250, (float)2.375854, (float)2.647583,
pascal@12756	5316 (float)1.801392, (float)2.128052, (float)2.399780, (float)2.822876,
pascal@12756	5317 (float)1.853638, (float)2.066650, (float)2.429199, (float)2.751465,
pascal@12756	5318 (float)1.956299, (float)2.163696, (float)2.394775, (float)2.734253,
pascal@12756	5319
pascal@12756	5320
pascal@12756	5321
pascal@12756	5322 Andersen, et al. Experimental [Page 95]
pascal@12756	5323
pascal@12756	5324 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5325
pascal@12756	5326
pascal@12756	5327 (float)1.963623, (float)2.275757, (float)2.585327, (float)2.865234,
pascal@12756	5328 (float)1.887451, (float)2.105469, (float)2.331787, (float)2.587402,
pascal@12756	5329 (float)2.120117, (float)2.443359, (float)2.733887, (float)2.941406,
pascal@12756	5330 (float)1.506348, (float)1.766968, (float)2.400513, (float)2.851807,
pascal@12756	5331 (float)1.664551, (float)1.981079, (float)2.375732, (float)2.774414,
pascal@12756	5332 (float)1.720703, (float)1.978882, (float)2.391479, (float)2.640991,
pascal@12756	5333 (float)1.483398, (float)1.814819, (float)2.434448, (float)2.722290,
pascal@12756	5334 (float)1.769043, (float)2.136597, (float)2.563721, (float)2.774414,
pascal@12756	5335 (float)1.810791, (float)2.049316, (float)2.373901, (float)2.613647,
pascal@12756	5336 (float)1.788330, (float)2.005981, (float)2.359131, (float)2.723145,
pascal@12756	5337 (float)1.785156, (float)1.993164, (float)2.399780, (float)2.832520,
pascal@12756	5338 (float)1.695313, (float)2.022949, (float)2.522583, (float)2.745117,
pascal@12756	5339 (float)1.584106, (float)1.965576, (float)2.299927, (float)2.715576,
pascal@12756	5340 (float)1.894897, (float)2.249878, (float)2.655884, (float)2.897705,
pascal@12756	5341 (float)1.720581, (float)1.995728, (float)2.299438, (float)2.557007,
pascal@12756	5342 (float)1.619385, (float)2.173950, (float)2.574219, (float)2.787964,
pascal@12756	5343 (float)1.883179, (float)2.220459, (float)2.474365, (float)2.825073,
pascal@12756	5344 (float)1.447632, (float)2.045044, (float)2.555542, (float)2.744873,
pascal@12756	5345 (float)1.502686, (float)2.156616, (float)2.653320, (float)2.846558,
pascal@12756	5346 (float)1.711548, (float)1.944092, (float)2.282959, (float)2.685791,
pascal@12756	5347 (float)1.499756, (float)1.867554, (float)2.341064, (float)2.578857,
pascal@12756	5348 (float)1.916870, (float)2.135132, (float)2.568237, (float)2.826050,
pascal@12756	5349 (float)1.498047, (float)1.711182, (float)2.223267, (float)2.755127,
pascal@12756	5350 (float)1.808716, (float)1.997559, (float)2.256470, (float)2.758545,
pascal@12756	5351 (float)2.088501, (float)2.402710, (float)2.667358, (float)2.890259,
pascal@12756	5352 (float)1.545044, (float)1.819214, (float)2.324097, (float)2.692993,
pascal@12756	5353 (float)1.796021, (float)2.012573, (float)2.505737, (float)2.784912,
pascal@12756	5354 (float)1.786499, (float)2.041748, (float)2.290405, (float)2.650757,
pascal@12756	5355 (float)1.938232, (float)2.264404, (float)2.529053, (float)2.796143
pascal@12756	5356 };
pascal@12756	5357
pascal@12756	5358 A.9. anaFilter.h
pascal@12756	5359
pascal@12756	5360 /******************************************************************
pascal@12756	5361
pascal@12756	5362 iLBC Speech Coder ANSI-C Source Code
pascal@12756	5363
pascal@12756	5364 anaFilter.h
pascal@12756	5365
pascal@12756	5366 Copyright (C) The Internet Society (2004).
pascal@12756	5367 All Rights Reserved.
pascal@12756	5368
pascal@12756	5369 ******************************************************************/
pascal@12756	5370
pascal@12756	5371 #ifndef __iLBC_ANAFILTER_H
pascal@12756	5372 #define __iLBC_ANAFILTER_H
pascal@12756	5373
pascal@12756	5374 void anaFilter(
pascal@12756	5375
pascal@12756	5376
pascal@12756	5377
pascal@12756	5378 Andersen, et al. Experimental [Page 96]
pascal@12756	5379
pascal@12756	5380 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5381
pascal@12756	5382
pascal@12756	5383 float In, / (i) Signal to be filtered */
pascal@12756	5384 float a, / (i) LP parameters */
pascal@12756	5385 int len,/* (i) Length of signal */
pascal@12756	5386 float Out, / (o) Filtered signal */
pascal@12756	5387 float mem / (i/o) Filter state */
pascal@12756	5388 );
pascal@12756	5389
pascal@12756	5390 #endif
pascal@12756	5391
pascal@12756	5392 A.10. anaFilter.c
pascal@12756	5393
pascal@12756	5394 /******************************************************************
pascal@12756	5395
pascal@12756	5396 iLBC Speech Coder ANSI-C Source Code
pascal@12756	5397
pascal@12756	5398 anaFilter.c
pascal@12756	5399
pascal@12756	5400 Copyright (C) The Internet Society (2004).
pascal@12756	5401 All Rights Reserved.
pascal@12756	5402
pascal@12756	5403 ******************************************************************/
pascal@12756	5404
pascal@12756	5405 #include <string.h>
pascal@12756	5406 #include "iLBC_define.h"
pascal@12756	5407
pascal@12756	5408 /----------------------------------------------------------------
pascal@12756	5409 * LP analysis filter.
pascal@12756	5410 ---------------------------------------------------------------/
pascal@12756	5411
pascal@12756	5412 void anaFilter(
pascal@12756	5413 float In, / (i) Signal to be filtered */
pascal@12756	5414 float a, / (i) LP parameters */
pascal@12756	5415 int len,/* (i) Length of signal */
pascal@12756	5416 float Out, / (o) Filtered signal */
pascal@12756	5417 float mem / (i/o) Filter state */
pascal@12756	5418 ){
pascal@12756	5419 int i, j;
pascal@12756	5420 float po, pi, pm, pa;
pascal@12756	5421
pascal@12756	5422 po = Out;
pascal@12756	5423
pascal@12756	5424 /* Filter first part using memory from past */
pascal@12756	5425
pascal@12756	5426 for (i=0; i<LPC_FILTERORDER; i++) {
pascal@12756	5427 pi = &In[i];
pascal@12756	5428 pm = &mem[LPC_FILTERORDER-1];
pascal@12756	5429 pa = a;
pascal@12756	5430 *po=0.0;
pascal@12756	5431
pascal@12756	5432
pascal@12756	5433
pascal@12756	5434 Andersen, et al. Experimental [Page 97]
pascal@12756	5435
pascal@12756	5436 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5437
pascal@12756	5438
pascal@12756	5439 for (j=0; j<=i; j++) {
pascal@12756	5440 po+=(pa++)(pi--);
pascal@12756	5441 }
pascal@12756	5442 for (j=i+1; j<LPC_FILTERORDER+1; j++) {
pascal@12756	5443
pascal@12756	5444 po+=(pa++)(pm--);
pascal@12756	5445 }
pascal@12756	5446 po++;
pascal@12756	5447 }
pascal@12756	5448
pascal@12756	5449 /* Filter last part where the state is entirely
pascal@12756	5450 in the input vector */
pascal@12756	5451
pascal@12756	5452 for (i=LPC_FILTERORDER; i<len; i++) {
pascal@12756	5453 pi = &In[i];
pascal@12756	5454 pa = a;
pascal@12756	5455 *po=0.0;
pascal@12756	5456 for (j=0; j<LPC_FILTERORDER+1; j++) {
pascal@12756	5457 po+=(pa++)(pi--);
pascal@12756	5458 }
pascal@12756	5459 po++;
pascal@12756	5460 }
pascal@12756	5461
pascal@12756	5462 /* Update state vector */
pascal@12756	5463
pascal@12756	5464 memcpy(mem, &In[len-LPC_FILTERORDER],
pascal@12756	5465 LPC_FILTERORDER*sizeof(float));
pascal@12756	5466 }
pascal@12756	5467
pascal@12756	5468 A.11. createCB.h
pascal@12756	5469
pascal@12756	5470 /******************************************************************
pascal@12756	5471
pascal@12756	5472 iLBC Speech Coder ANSI-C Source Code
pascal@12756	5473
pascal@12756	5474 createCB.h
pascal@12756	5475
pascal@12756	5476 Copyright (C) The Internet Society (2004).
pascal@12756	5477 All Rights Reserved.
pascal@12756	5478
pascal@12756	5479 ******************************************************************/
pascal@12756	5480
pascal@12756	5481 #ifndef __iLBC_CREATECB_H
pascal@12756	5482 #define __iLBC_CREATECB_H
pascal@12756	5483
pascal@12756	5484 void filteredCBvecs(
pascal@12756	5485 float cbvectors, / (o) Codebook vector for the
pascal@12756	5486 higher section */
pascal@12756	5487
pascal@12756	5488
pascal@12756	5489
pascal@12756	5490 Andersen, et al. Experimental [Page 98]
pascal@12756	5491
pascal@12756	5492 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5493
pascal@12756	5494
pascal@12756	5495 float mem, / (i) Buffer to create codebook
pascal@12756	5496 vectors from */
pascal@12756	5497 int lMem /* (i) Length of buffer */
pascal@12756	5498 );
pascal@12756	5499
pascal@12756	5500 void searchAugmentedCB(
pascal@12756	5501 int low, /* (i) Start index for the search */
pascal@12756	5502 int high, /* (i) End index for the search */
pascal@12756	5503 int stage, /* (i) Current stage */
pascal@12756	5504 int startIndex, /* (i) CB index for the first
pascal@12756	5505 augmented vector */
pascal@12756	5506 float target, / (i) Target vector for encoding */
pascal@12756	5507 float buffer, / (i) Pointer to the end of the
pascal@12756	5508 buffer for augmented codebook
pascal@12756	5509 construction */
pascal@12756	5510 float max_measure, / (i/o) Currently maximum measure */
pascal@12756	5511 int best_index,/ (o) Currently the best index */
pascal@12756	5512 float gain, / (o) Currently the best gain */
pascal@12756	5513 float energy, / (o) Energy of augmented
pascal@12756	5514 codebook vectors */
pascal@12756	5515 float invenergy/ (o) Inv energy of aug codebook
pascal@12756	5516 vectors */
pascal@12756	5517 );
pascal@12756	5518
pascal@12756	5519 void createAugmentedVec(
pascal@12756	5520 int index, /* (i) Index for the aug vector
pascal@12756	5521 to be created */
pascal@12756	5522 float buffer, / (i) Pointer to the end of the
pascal@12756	5523 buffer for augmented codebook
pascal@12756	5524 construction */
pascal@12756	5525 float cbVec / (o) The construced codebook vector */
pascal@12756	5526 );
pascal@12756	5527
pascal@12756	5528 #endif
pascal@12756	5529
pascal@12756	5530 A.12. createCB.c
pascal@12756	5531
pascal@12756	5532
pascal@12756	5533 /******************************************************************
pascal@12756	5534
pascal@12756	5535 iLBC Speech Coder ANSI-C Source Code
pascal@12756	5536
pascal@12756	5537 createCB.c
pascal@12756	5538
pascal@12756	5539 Copyright (C) The Internet Society (2004).
pascal@12756	5540 All Rights Reserved.
pascal@12756	5541
pascal@12756	5542 ******************************************************************/
pascal@12756	5543
pascal@12756	5544
pascal@12756	5545
pascal@12756	5546 Andersen, et al. Experimental [Page 99]
pascal@12756	5547
pascal@12756	5548 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5549
pascal@12756	5550
pascal@12756	5551 #include "iLBC_define.h"
pascal@12756	5552 #include "constants.h"
pascal@12756	5553 #include <string.h>
pascal@12756	5554 #include <math.h>
pascal@12756	5555
pascal@12756	5556 /----------------------------------------------------------------
pascal@12756	5557 * Construct an additional codebook vector by filtering the
pascal@12756	5558 * initial codebook buffer. This vector is then used to expand
pascal@12756	5559 * the codebook with an additional section.
pascal@12756	5560 ---------------------------------------------------------------/
pascal@12756	5561
pascal@12756	5562 void filteredCBvecs(
pascal@12756	5563 float cbvectors, / (o) Codebook vectors for the
pascal@12756	5564 higher section */
pascal@12756	5565 float mem, / (i) Buffer to create codebook
pascal@12756	5566 vector from */
pascal@12756	5567 int lMem /* (i) Length of buffer */
pascal@12756	5568 ){
pascal@12756	5569 int j, k;
pascal@12756	5570 float pp, pp1;
pascal@12756	5571 float tempbuff2[CB_MEML+CB_FILTERLEN];
pascal@12756	5572 float *pos;
pascal@12756	5573
pascal@12756	5574 memset(tempbuff2, 0, (CB_HALFFILTERLEN-1)*sizeof(float));
pascal@12756	5575 memcpy(&tempbuff2[CB_HALFFILTERLEN-1], mem, lMem*sizeof(float));
pascal@12756	5576 memset(&tempbuff2[lMem+CB_HALFFILTERLEN-1], 0,
pascal@12756	5577 (CB_HALFFILTERLEN+1)*sizeof(float));
pascal@12756	5578
pascal@12756	5579 /* Create codebook vector for higher section by filtering */
pascal@12756	5580
pascal@12756	5581 /* do filtering */
pascal@12756	5582 pos=cbvectors;
pascal@12756	5583 memset(pos, 0, lMem*sizeof(float));
pascal@12756	5584 for (k=0; k<lMem; k++) {
pascal@12756	5585 pp=&tempbuff2[k];
pascal@12756	5586 pp1=&cbfiltersTbl[CB_FILTERLEN-1];
pascal@12756	5587 for (j=0;j<CB_FILTERLEN;j++) {
pascal@12756	5588 (pos)+=(pp++)(pp1--);
pascal@12756	5589 }
pascal@12756	5590 pos++;
pascal@12756	5591 }
pascal@12756	5592 }
pascal@12756	5593
pascal@12756	5594 /----------------------------------------------------------------
pascal@12756	5595 * Search the augmented part of the codebook to find the best
pascal@12756	5596 * measure.
pascal@12756	5597 ----------------------------------------------------------------/
pascal@12756	5598
pascal@12756	5599
pascal@12756	5600
pascal@12756	5601
pascal@12756	5602 Andersen, et al. Experimental [Page 100]
pascal@12756	5603
pascal@12756	5604 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5605
pascal@12756	5606
pascal@12756	5607 void searchAugmentedCB(
pascal@12756	5608 int low, /* (i) Start index for the search */
pascal@12756	5609 int high, /* (i) End index for the search */
pascal@12756	5610 int stage, /* (i) Current stage */
pascal@12756	5611 int startIndex, /* (i) Codebook index for the first
pascal@12756	5612 aug vector */
pascal@12756	5613 float target, / (i) Target vector for encoding */
pascal@12756	5614 float buffer, / (i) Pointer to the end of the buffer for
pascal@12756	5615 augmented codebook construction */
pascal@12756	5616 float max_measure, / (i/o) Currently maximum measure */
pascal@12756	5617 int best_index,/ (o) Currently the best index */
pascal@12756	5618 float gain, / (o) Currently the best gain */
pascal@12756	5619 float energy, / (o) Energy of augmented codebook
pascal@12756	5620 vectors */
pascal@12756	5621 float invenergy/ (o) Inv energy of augmented codebook
pascal@12756	5622 vectors */
pascal@12756	5623 ) {
pascal@12756	5624 int icount, ilow, j, tmpIndex;
pascal@12756	5625 float pp, ppo, ppi, ppe, crossDot, alfa;
pascal@12756	5626 float weighted, measure, nrjRecursive;
pascal@12756	5627 float ftmp;
pascal@12756	5628
pascal@12756	5629 /* Compute the energy for the first (low-5)
pascal@12756	5630 noninterpolated samples */
pascal@12756	5631 nrjRecursive = (float) 0.0;
pascal@12756	5632 pp = buffer - low + 1;
pascal@12756	5633 for (j=0; j<(low-5); j++) {
pascal@12756	5634 nrjRecursive += ( (pp)(*pp) );
pascal@12756	5635 pp++;
pascal@12756	5636 }
pascal@12756	5637 ppe = buffer - low;
pascal@12756	5638
pascal@12756	5639
pascal@12756	5640 for (icount=low; icount<=high; icount++) {
pascal@12756	5641
pascal@12756	5642 /* Index of the codebook vector used for retrieving
pascal@12756	5643 energy values */
pascal@12756	5644 tmpIndex = startIndex+icount-20;
pascal@12756	5645
pascal@12756	5646 ilow = icount-4;
pascal@12756	5647
pascal@12756	5648 /* Update the energy recursively to save complexity */
pascal@12756	5649 nrjRecursive = nrjRecursive + (ppe)(*ppe);
pascal@12756	5650 ppe--;
pascal@12756	5651 energy[tmpIndex] = nrjRecursive;
pascal@12756	5652
pascal@12756	5653 /* Compute cross dot product for the first (low-5)
pascal@12756	5654 samples */
pascal@12756	5655
pascal@12756	5656
pascal@12756	5657
pascal@12756	5658 Andersen, et al. Experimental [Page 101]
pascal@12756	5659
pascal@12756	5660 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5661
pascal@12756	5662
pascal@12756	5663 crossDot = (float) 0.0;
pascal@12756	5664 pp = buffer-icount;
pascal@12756	5665 for (j=0; j<ilow; j++) {
pascal@12756	5666 crossDot += target[j](pp++);
pascal@12756	5667 }
pascal@12756	5668
pascal@12756	5669 /* interpolation */
pascal@12756	5670 alfa = (float) 0.2;
pascal@12756	5671 ppo = buffer-4;
pascal@12756	5672 ppi = buffer-icount-4;
pascal@12756	5673 for (j=ilow; j<icount; j++) {
pascal@12756	5674 weighted = ((float)1.0-alfa)(ppo)+alfa(ppi);
pascal@12756	5675 ppo++;
pascal@12756	5676 ppi++;
pascal@12756	5677 energy[tmpIndex] += weighted*weighted;
pascal@12756	5678 crossDot += target[j]*weighted;
pascal@12756	5679 alfa += (float)0.2;
pascal@12756	5680 }
pascal@12756	5681
pascal@12756	5682 /* Compute energy and cross dot product for the
pascal@12756	5683 remaining samples */
pascal@12756	5684 pp = buffer - icount;
pascal@12756	5685 for (j=icount; j<SUBL; j++) {
pascal@12756	5686 energy[tmpIndex] += (pp)(*pp);
pascal@12756	5687 crossDot += target[j](pp++);
pascal@12756	5688 }
pascal@12756	5689
pascal@12756	5690 if (energy[tmpIndex]>0.0) {
pascal@12756	5691 invenergy[tmpIndex]=(float)1.0/(energy[tmpIndex]+EPS);
pascal@12756	5692 } else {
pascal@12756	5693 invenergy[tmpIndex] = (float) 0.0;
pascal@12756	5694 }
pascal@12756	5695
pascal@12756	5696 if (stage==0) {
pascal@12756	5697 measure = (float)-10000000.0;
pascal@12756	5698
pascal@12756	5699 if (crossDot > 0.0) {
pascal@12756	5700 measure = crossDotcrossDotinvenergy[tmpIndex];
pascal@12756	5701 }
pascal@12756	5702 }
pascal@12756	5703 else {
pascal@12756	5704 measure = crossDotcrossDotinvenergy[tmpIndex];
pascal@12756	5705 }
pascal@12756	5706
pascal@12756	5707 /* check if measure is better */
pascal@12756	5708 ftmp = crossDot*invenergy[tmpIndex];
pascal@12756	5709
pascal@12756	5710 if ((measure>*max_measure) && (fabs(ftmp)<CB_MAXGAIN)) {
pascal@12756	5711
pascal@12756	5712
pascal@12756	5713
pascal@12756	5714 Andersen, et al. Experimental [Page 102]
pascal@12756	5715
pascal@12756	5716 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5717
pascal@12756	5718
pascal@12756	5719 *best_index = tmpIndex;
pascal@12756	5720 *max_measure = measure;
pascal@12756	5721 *gain = ftmp;
pascal@12756	5722 }
pascal@12756	5723 }
pascal@12756	5724 }
pascal@12756	5725
pascal@12756	5726
pascal@12756	5727 /----------------------------------------------------------------
pascal@12756	5728 * Recreate a specific codebook vector from the augmented part.
pascal@12756	5729 *
pascal@12756	5730 ----------------------------------------------------------------/
pascal@12756	5731
pascal@12756	5732 void createAugmentedVec(
pascal@12756	5733 int index, /* (i) Index for the augmented vector
pascal@12756	5734 to be created */
pascal@12756	5735 float buffer, / (i) Pointer to the end of the buffer for
pascal@12756	5736 augmented codebook construction */
pascal@12756	5737 float cbVec/ (o) The construced codebook vector */
pascal@12756	5738 ) {
pascal@12756	5739 int ilow, j;
pascal@12756	5740 float pp, ppo, *ppi, alfa, alfa1, weighted;
pascal@12756	5741
pascal@12756	5742 ilow = index-5;
pascal@12756	5743
pascal@12756	5744 /* copy the first noninterpolated part */
pascal@12756	5745
pascal@12756	5746 pp = buffer-index;
pascal@12756	5747 memcpy(cbVec,pp,sizeof(float)*index);
pascal@12756	5748
pascal@12756	5749 /* interpolation */
pascal@12756	5750
pascal@12756	5751 alfa1 = (float)0.2;
pascal@12756	5752 alfa = 0.0;
pascal@12756	5753 ppo = buffer-5;
pascal@12756	5754 ppi = buffer-index-5;
pascal@12756	5755 for (j=ilow; j<index; j++) {
pascal@12756	5756 weighted = ((float)1.0-alfa)(ppo)+alfa(ppi);
pascal@12756	5757 ppo++;
pascal@12756	5758 ppi++;
pascal@12756	5759 cbVec[j] = weighted;
pascal@12756	5760 alfa += alfa1;
pascal@12756	5761 }
pascal@12756	5762
pascal@12756	5763 /* copy the second noninterpolated part */
pascal@12756	5764
pascal@12756	5765 pp = buffer - index;
pascal@12756	5766 memcpy(cbVec+index,pp,sizeof(float)*(SUBL-index));
pascal@12756	5767
pascal@12756	5768
pascal@12756	5769
pascal@12756	5770 Andersen, et al. Experimental [Page 103]
pascal@12756	5771
pascal@12756	5772 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5773
pascal@12756	5774
pascal@12756	5775 }
pascal@12756	5776
pascal@12756	5777 A.13. doCPLC.h
pascal@12756	5778
pascal@12756	5779 /******************************************************************
pascal@12756	5780
pascal@12756	5781 iLBC Speech Coder ANSI-C Source Code
pascal@12756	5782
pascal@12756	5783 doCPLC.h
pascal@12756	5784
pascal@12756	5785 Copyright (C) The Internet Society (2004).
pascal@12756	5786 All Rights Reserved.
pascal@12756	5787
pascal@12756	5788 ******************************************************************/
pascal@12756	5789
pascal@12756	5790 #ifndef __iLBC_DOLPC_H
pascal@12756	5791 #define __iLBC_DOLPC_H
pascal@12756	5792
pascal@12756	5793 void doThePLC(
pascal@12756	5794 float PLCresidual, / (o) concealed residual */
pascal@12756	5795 float PLClpc, / (o) concealed LP parameters */
pascal@12756	5796 int PLI, /* (i) packet loss indicator
pascal@12756	5797 0 - no PL, 1 = PL */
pascal@12756	5798 float decresidual, / (i) decoded residual */
pascal@12756	5799 float lpc, / (i) decoded LPC (only used for no PL) */
pascal@12756	5800 int inlag, /* (i) pitch lag */
pascal@12756	5801 iLBC_Dec_Inst_t *iLBCdec_inst
pascal@12756	5802 /* (i/o) decoder instance */
pascal@12756	5803 );
pascal@12756	5804
pascal@12756	5805 #endif
pascal@12756	5806
pascal@12756	5807 A.14. doCPLC.c
pascal@12756	5808
pascal@12756	5809 /******************************************************************
pascal@12756	5810
pascal@12756	5811 iLBC Speech Coder ANSI-C Source Code
pascal@12756	5812
pascal@12756	5813 doCPLC.c
pascal@12756	5814
pascal@12756	5815 Copyright (C) The Internet Society (2004).
pascal@12756	5816 All Rights Reserved.
pascal@12756	5817
pascal@12756	5818 ******************************************************************/
pascal@12756	5819
pascal@12756	5820 #include <math.h>
pascal@12756	5821 #include <string.h>
pascal@12756	5822 #include <stdio.h>
pascal@12756	5823
pascal@12756	5824
pascal@12756	5825
pascal@12756	5826 Andersen, et al. Experimental [Page 104]
pascal@12756	5827
pascal@12756	5828 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5829
pascal@12756	5830
pascal@12756	5831 #include "iLBC_define.h"
pascal@12756	5832
pascal@12756	5833 /----------------------------------------------------------------
pascal@12756	5834 * Compute cross correlation and pitch gain for pitch prediction
pascal@12756	5835 * of last subframe at given lag.
pascal@12756	5836 ---------------------------------------------------------------/
pascal@12756	5837
pascal@12756	5838 void compCorr(
pascal@12756	5839 float cc, / (o) cross correlation coefficient */
pascal@12756	5840 float gc, / (o) gain */
pascal@12756	5841 float *pm,
pascal@12756	5842 float buffer, / (i) signal buffer */
pascal@12756	5843 int lag, /* (i) pitch lag */
pascal@12756	5844 int bLen, /* (i) length of buffer */
pascal@12756	5845 int sRange /* (i) correlation search length */
pascal@12756	5846 ){
pascal@12756	5847 int i;
pascal@12756	5848 float ftmp1, ftmp2, ftmp3;
pascal@12756	5849
pascal@12756	5850 /* Guard against getting outside buffer */
pascal@12756	5851 if ((bLen-sRange-lag)<0) {
pascal@12756	5852 sRange=bLen-lag;
pascal@12756	5853 }
pascal@12756	5854
pascal@12756	5855 ftmp1 = 0.0;
pascal@12756	5856 ftmp2 = 0.0;
pascal@12756	5857 ftmp3 = 0.0;
pascal@12756	5858 for (i=0; i<sRange; i++) {
pascal@12756	5859 ftmp1 += buffer[bLen-sRange+i] *
pascal@12756	5860 buffer[bLen-sRange+i-lag];
pascal@12756	5861 ftmp2 += buffer[bLen-sRange+i-lag] *
pascal@12756	5862 buffer[bLen-sRange+i-lag];
pascal@12756	5863 ftmp3 += buffer[bLen-sRange+i] *
pascal@12756	5864 buffer[bLen-sRange+i];
pascal@12756	5865 }
pascal@12756	5866
pascal@12756	5867 if (ftmp2 > 0.0) {
pascal@12756	5868 cc = ftmp1ftmp1/ftmp2;
pascal@12756	5869 *gc = (float)fabs(ftmp1/ftmp2);
pascal@12756	5870 *pm=(float)fabs(ftmp1)/
pascal@12756	5871 ((float)sqrt(ftmp2)*(float)sqrt(ftmp3));
pascal@12756	5872 }
pascal@12756	5873 else {
pascal@12756	5874 *cc = 0.0;
pascal@12756	5875 *gc = 0.0;
pascal@12756	5876 *pm=0.0;
pascal@12756	5877 }
pascal@12756	5878 }
pascal@12756	5879
pascal@12756	5880
pascal@12756	5881
pascal@12756	5882 Andersen, et al. Experimental [Page 105]
pascal@12756	5883
pascal@12756	5884 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5885
pascal@12756	5886
pascal@12756	5887 /----------------------------------------------------------------
pascal@12756	5888 * Packet loss concealment routine. Conceals a residual signal
pascal@12756	5889 * and LP parameters. If no packet loss, update state.
pascal@12756	5890 ---------------------------------------------------------------/
pascal@12756	5891
pascal@12756	5892 void doThePLC(
pascal@12756	5893 float PLCresidual, / (o) concealed residual */
pascal@12756	5894 float PLClpc, / (o) concealed LP parameters */
pascal@12756	5895 int PLI, /* (i) packet loss indicator
pascal@12756	5896 0 - no PL, 1 = PL */
pascal@12756	5897 float decresidual, / (i) decoded residual */
pascal@12756	5898 float lpc, / (i) decoded LPC (only used for no PL) */
pascal@12756	5899 int inlag, /* (i) pitch lag */
pascal@12756	5900 iLBC_Dec_Inst_t *iLBCdec_inst
pascal@12756	5901 /* (i/o) decoder instance */
pascal@12756	5902 ){
pascal@12756	5903 int lag=20, randlag;
pascal@12756	5904 float gain, maxcc;
pascal@12756	5905 float use_gain;
pascal@12756	5906 float gain_comp, maxcc_comp, per, max_per;
pascal@12756	5907 int i, pick, use_lag;
pascal@12756	5908 float ftmp, randvec[BLOCKL_MAX], pitchfact, energy;
pascal@12756	5909
pascal@12756	5910 /* Packet Loss */
pascal@12756	5911
pascal@12756	5912 if (PLI == 1) {
pascal@12756	5913
pascal@12756	5914 iLBCdec_inst->consPLICount += 1;
pascal@12756	5915
pascal@12756	5916 /* if previous frame not lost,
pascal@12756	5917 determine pitch pred. gain */
pascal@12756	5918
pascal@12756	5919 if (iLBCdec_inst->prevPLI != 1) {
pascal@12756	5920
pascal@12756	5921 /* Search around the previous lag to find the
pascal@12756	5922 best pitch period */
pascal@12756	5923
pascal@12756	5924 lag=inlag-3;
pascal@12756	5925 compCorr(&maxcc, &gain, &max_per,
pascal@12756	5926 iLBCdec_inst->prevResidual,
pascal@12756	5927 lag, iLBCdec_inst->blockl, 60);
pascal@12756	5928 for (i=inlag-2;i<=inlag+3;i++) {
pascal@12756	5929 compCorr(&maxcc_comp, &gain_comp, &per,
pascal@12756	5930 iLBCdec_inst->prevResidual,
pascal@12756	5931 i, iLBCdec_inst->blockl, 60);
pascal@12756	5932
pascal@12756	5933 if (maxcc_comp>maxcc) {
pascal@12756	5934 maxcc=maxcc_comp;
pascal@12756	5935
pascal@12756	5936
pascal@12756	5937
pascal@12756	5938 Andersen, et al. Experimental [Page 106]
pascal@12756	5939
pascal@12756	5940 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5941
pascal@12756	5942
pascal@12756	5943 gain=gain_comp;
pascal@12756	5944 lag=i;
pascal@12756	5945 max_per=per;
pascal@12756	5946 }
pascal@12756	5947 }
pascal@12756	5948
pascal@12756	5949 }
pascal@12756	5950
pascal@12756	5951 /* previous frame lost, use recorded lag and periodicity */
pascal@12756	5952
pascal@12756	5953 else {
pascal@12756	5954 lag=iLBCdec_inst->prevLag;
pascal@12756	5955 max_per=iLBCdec_inst->per;
pascal@12756	5956 }
pascal@12756	5957
pascal@12756	5958 /* downscaling */
pascal@12756	5959
pascal@12756	5960 use_gain=1.0;
pascal@12756	5961 if (iLBCdec_inst->consPLICount*iLBCdec_inst->blockl>320)
pascal@12756	5962 use_gain=(float)0.9;
pascal@12756	5963 else if (iLBCdec_inst->consPLICount*
pascal@12756	5964 iLBCdec_inst->blockl>2*320)
pascal@12756	5965 use_gain=(float)0.7;
pascal@12756	5966 else if (iLBCdec_inst->consPLICount*
pascal@12756	5967 iLBCdec_inst->blockl>3*320)
pascal@12756	5968 use_gain=(float)0.5;
pascal@12756	5969 else if (iLBCdec_inst->consPLICount*
pascal@12756	5970 iLBCdec_inst->blockl>4*320)
pascal@12756	5971 use_gain=(float)0.0;
pascal@12756	5972
pascal@12756	5973 /* mix noise and pitch repeatition */
pascal@12756	5974 ftmp=(float)sqrt(max_per);
pascal@12756	5975 if (ftmp>(float)0.7)
pascal@12756	5976 pitchfact=(float)1.0;
pascal@12756	5977 else if (ftmp>(float)0.4)
pascal@12756	5978 pitchfact=(ftmp-(float)0.4)/((float)0.7-(float)0.4);
pascal@12756	5979 else
pascal@12756	5980 pitchfact=0.0;
pascal@12756	5981
pascal@12756	5982
pascal@12756	5983 /* avoid repetition of same pitch cycle */
pascal@12756	5984 use_lag=lag;
pascal@12756	5985 if (lag<80) {
pascal@12756	5986 use_lag=2*lag;
pascal@12756	5987 }
pascal@12756	5988
pascal@12756	5989 /* compute concealed residual */
pascal@12756	5990
pascal@12756	5991
pascal@12756	5992
pascal@12756	5993
pascal@12756	5994 Andersen, et al. Experimental [Page 107]
pascal@12756	5995
pascal@12756	5996 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	5997
pascal@12756	5998
pascal@12756	5999 energy = 0.0;
pascal@12756	6000 for (i=0; i<iLBCdec_inst->blockl; i++) {
pascal@12756	6001
pascal@12756	6002 /* noise component */
pascal@12756	6003
pascal@12756	6004 iLBCdec_inst->seed=(iLBCdec_inst->seed*69069L+1) &
pascal@12756	6005 (0x80000000L-1);
pascal@12756	6006 randlag = 50 + ((signed long) iLBCdec_inst->seed)%70;
pascal@12756	6007 pick = i - randlag;
pascal@12756	6008
pascal@12756	6009 if (pick < 0) {
pascal@12756	6010 randvec[i] =
pascal@12756	6011 iLBCdec_inst->prevResidual[
pascal@12756	6012 iLBCdec_inst->blockl+pick];
pascal@12756	6013 } else {
pascal@12756	6014 randvec[i] = randvec[pick];
pascal@12756	6015 }
pascal@12756	6016
pascal@12756	6017 /* pitch repeatition component */
pascal@12756	6018 pick = i - use_lag;
pascal@12756	6019
pascal@12756	6020 if (pick < 0) {
pascal@12756	6021 PLCresidual[i] =
pascal@12756	6022 iLBCdec_inst->prevResidual[
pascal@12756	6023 iLBCdec_inst->blockl+pick];
pascal@12756	6024 } else {
pascal@12756	6025 PLCresidual[i] = PLCresidual[pick];
pascal@12756	6026 }
pascal@12756	6027
pascal@12756	6028 /* mix random and periodicity component */
pascal@12756	6029
pascal@12756	6030 if (i<80)
pascal@12756	6031 PLCresidual[i] = use_gain(pitchfact
pascal@12756	6032 PLCresidual[i] +
pascal@12756	6033 ((float)1.0 - pitchfact) * randvec[i]);
pascal@12756	6034 else if (i<160)
pascal@12756	6035 PLCresidual[i] = (float)0.95use_gain(pitchfact *
pascal@12756	6036 PLCresidual[i] +
pascal@12756	6037 ((float)1.0 - pitchfact) * randvec[i]);
pascal@12756	6038 else
pascal@12756	6039 PLCresidual[i] = (float)0.9use_gain(pitchfact *
pascal@12756	6040 PLCresidual[i] +
pascal@12756	6041 ((float)1.0 - pitchfact) * randvec[i]);
pascal@12756	6042
pascal@12756	6043 energy += PLCresidual[i] * PLCresidual[i];
pascal@12756	6044 }
pascal@12756	6045
pascal@12756	6046 /* less than 30 dB, use only noise */
pascal@12756	6047
pascal@12756	6048
pascal@12756	6049
pascal@12756	6050 Andersen, et al. Experimental [Page 108]
pascal@12756	6051
pascal@12756	6052 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6053
pascal@12756	6054
pascal@12756	6055
pascal@12756	6056 if (sqrt(energy/(float)iLBCdec_inst->blockl) < 30.0) {
pascal@12756	6057 gain=0.0;
pascal@12756	6058 for (i=0; i<iLBCdec_inst->blockl; i++) {
pascal@12756	6059 PLCresidual[i] = randvec[i];
pascal@12756	6060 }
pascal@12756	6061 }
pascal@12756	6062
pascal@12756	6063 /* use old LPC */
pascal@12756	6064
pascal@12756	6065 memcpy(PLClpc,iLBCdec_inst->prevLpc,
pascal@12756	6066 (LPC_FILTERORDER+1)*sizeof(float));
pascal@12756	6067
pascal@12756	6068 }
pascal@12756	6069
pascal@12756	6070 /* no packet loss, copy input */
pascal@12756	6071
pascal@12756	6072 else {
pascal@12756	6073 memcpy(PLCresidual, decresidual,
pascal@12756	6074 iLBCdec_inst->blockl*sizeof(float));
pascal@12756	6075 memcpy(PLClpc, lpc, (LPC_FILTERORDER+1)*sizeof(float));
pascal@12756	6076 iLBCdec_inst->consPLICount = 0;
pascal@12756	6077 }
pascal@12756	6078
pascal@12756	6079 /* update state */
pascal@12756	6080
pascal@12756	6081 if (PLI) {
pascal@12756	6082 iLBCdec_inst->prevLag = lag;
pascal@12756	6083 iLBCdec_inst->per=max_per;
pascal@12756	6084 }
pascal@12756	6085
pascal@12756	6086 iLBCdec_inst->prevPLI = PLI;
pascal@12756	6087 memcpy(iLBCdec_inst->prevLpc, PLClpc,
pascal@12756	6088 (LPC_FILTERORDER+1)*sizeof(float));
pascal@12756	6089 memcpy(iLBCdec_inst->prevResidual, PLCresidual,
pascal@12756	6090 iLBCdec_inst->blockl*sizeof(float));
pascal@12756	6091 }
pascal@12756	6092
pascal@12756	6093 A.15. enhancer.h
pascal@12756	6094
pascal@12756	6095 /******************************************************************
pascal@12756	6096
pascal@12756	6097 iLBC Speech Coder ANSI-C Source Code
pascal@12756	6098
pascal@12756	6099 enhancer.h
pascal@12756	6100
pascal@12756	6101 Copyright (C) The Internet Society (2004).
pascal@12756	6102 All Rights Reserved.
pascal@12756	6103
pascal@12756	6104
pascal@12756	6105
pascal@12756	6106 Andersen, et al. Experimental [Page 109]
pascal@12756	6107
pascal@12756	6108 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6109
pascal@12756	6110
pascal@12756	6111 ******************************************************************/
pascal@12756	6112
pascal@12756	6113 #ifndef __ENHANCER_H
pascal@12756	6114 #define __ENHANCER_H
pascal@12756	6115
pascal@12756	6116 #include "iLBC_define.h"
pascal@12756	6117
pascal@12756	6118 float xCorrCoef(
pascal@12756	6119 float target, / (i) first array */
pascal@12756	6120 float regressor, / (i) second array */
pascal@12756	6121 int subl /* (i) dimension arrays */
pascal@12756	6122 );
pascal@12756	6123
pascal@12756	6124 int enhancerInterface(
pascal@12756	6125 float out, / (o) the enhanced recidual signal */
pascal@12756	6126 float in, / (i) the recidual signal to enhance */
pascal@12756	6127 iLBC_Dec_Inst_t *iLBCdec_inst
pascal@12756	6128 /* (i/o) the decoder state structure */
pascal@12756	6129 );
pascal@12756	6130
pascal@12756	6131 #endif
pascal@12756	6132
pascal@12756	6133 A.16. enhancer.c
pascal@12756	6134
pascal@12756	6135 /******************************************************************
pascal@12756	6136
pascal@12756	6137 iLBC Speech Coder ANSI-C Source Code
pascal@12756	6138
pascal@12756	6139 enhancer.c
pascal@12756	6140
pascal@12756	6141 Copyright (C) The Internet Society (2004).
pascal@12756	6142 All Rights Reserved.
pascal@12756	6143
pascal@12756	6144 ******************************************************************/
pascal@12756	6145
pascal@12756	6146 #include <math.h>
pascal@12756	6147 #include <string.h>
pascal@12756	6148 #include "iLBC_define.h"
pascal@12756	6149 #include "constants.h"
pascal@12756	6150 #include "filter.h"
pascal@12756	6151
pascal@12756	6152 /----------------------------------------------------------------
pascal@12756	6153 * Find index in array such that the array element with said
pascal@12756	6154 * index is the element of said array closest to "value"
pascal@12756	6155 * according to the squared-error criterion
pascal@12756	6156 ---------------------------------------------------------------/
pascal@12756	6157
pascal@12756	6158 void NearestNeighbor(
pascal@12756	6159
pascal@12756	6160
pascal@12756	6161
pascal@12756	6162 Andersen, et al. Experimental [Page 110]
pascal@12756	6163
pascal@12756	6164 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6165
pascal@12756	6166
pascal@12756	6167 int index, / (o) index of array element closest
pascal@12756	6168 to value */
pascal@12756	6169 float array, / (i) data array */
pascal@12756	6170 float value,/* (i) value */
pascal@12756	6171 int arlength/* (i) dimension of data array */
pascal@12756	6172 ){
pascal@12756	6173 int i;
pascal@12756	6174 float bestcrit,crit;
pascal@12756	6175
pascal@12756	6176 crit=array[0]-value;
pascal@12756	6177 bestcrit=crit*crit;
pascal@12756	6178 *index=0;
pascal@12756	6179 for (i=1; i<arlength; i++) {
pascal@12756	6180 crit=array[i]-value;
pascal@12756	6181 crit=crit*crit;
pascal@12756	6182
pascal@12756	6183 if (crit<bestcrit) {
pascal@12756	6184 bestcrit=crit;
pascal@12756	6185 *index=i;
pascal@12756	6186 }
pascal@12756	6187 }
pascal@12756	6188 }
pascal@12756	6189
pascal@12756	6190 /----------------------------------------------------------------
pascal@12756	6191 * compute cross correlation between sequences
pascal@12756	6192 ---------------------------------------------------------------/
pascal@12756	6193
pascal@12756	6194 void mycorr1(
pascal@12756	6195 float* corr, /* (o) correlation of seq1 and seq2 */
pascal@12756	6196 float* seq1, /* (i) first sequence */
pascal@12756	6197 int dim1, /* (i) dimension first seq1 */
pascal@12756	6198 const float seq2, / (i) second sequence */
pascal@12756	6199 int dim2 /* (i) dimension seq2 */
pascal@12756	6200 ){
pascal@12756	6201 int i,j;
pascal@12756	6202
pascal@12756	6203 for (i=0; i<=dim1-dim2; i++) {
pascal@12756	6204 corr[i]=0.0;
pascal@12756	6205 for (j=0; j<dim2; j++) {
pascal@12756	6206 corr[i] += seq1[i+j] * seq2[j];
pascal@12756	6207 }
pascal@12756	6208 }
pascal@12756	6209 }
pascal@12756	6210
pascal@12756	6211 /----------------------------------------------------------------
pascal@12756	6212 * upsample finite array assuming zeros outside bounds
pascal@12756	6213 ---------------------------------------------------------------/
pascal@12756	6214
pascal@12756	6215
pascal@12756	6216
pascal@12756	6217
pascal@12756	6218 Andersen, et al. Experimental [Page 111]
pascal@12756	6219
pascal@12756	6220 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6221
pascal@12756	6222
pascal@12756	6223 void enh_upsample(
pascal@12756	6224 float* useq1, /* (o) upsampled output sequence */
pascal@12756	6225 float* seq1,/* (i) unupsampled sequence */
pascal@12756	6226 int dim1, /* (i) dimension seq1 */
pascal@12756	6227 int hfl /* (i) polyphase filter length=2hfl+1 /
pascal@12756	6228 ){
pascal@12756	6229 float pu,ps;
pascal@12756	6230 int i,j,k,q,filterlength,hfl2;
pascal@12756	6231 const float polyp[ENH_UPS0]; / pointers to
pascal@12756	6232 polyphase columns */
pascal@12756	6233 const float *pp;
pascal@12756	6234
pascal@12756	6235 /* define pointers for filter */
pascal@12756	6236
pascal@12756	6237 filterlength=2*hfl+1;
pascal@12756	6238
pascal@12756	6239 if ( filterlength > dim1 ) {
pascal@12756	6240 hfl2=(int) (dim1/2);
pascal@12756	6241 for (j=0; j<ENH_UPS0; j++) {
pascal@12756	6242 polyp[j]=polyphaserTbl+j*filterlength+hfl-hfl2;
pascal@12756	6243 }
pascal@12756	6244 hfl=hfl2;
pascal@12756	6245 filterlength=2*hfl+1;
pascal@12756	6246 }
pascal@12756	6247 else {
pascal@12756	6248 for (j=0; j<ENH_UPS0; j++) {
pascal@12756	6249 polyp[j]=polyphaserTbl+j*filterlength;
pascal@12756	6250 }
pascal@12756	6251 }
pascal@12756	6252
pascal@12756	6253 /* filtering: filter overhangs left side of sequence */
pascal@12756	6254
pascal@12756	6255 pu=useq1;
pascal@12756	6256 for (i=hfl; i<filterlength; i++) {
pascal@12756	6257 for (j=0; j<ENH_UPS0; j++) {
pascal@12756	6258 *pu=0.0;
pascal@12756	6259 pp = polyp[j];
pascal@12756	6260 ps = seq1+i;
pascal@12756	6261 for (k=0; k<=i; k++) {
pascal@12756	6262 pu += ps-- * *pp++;
pascal@12756	6263 }
pascal@12756	6264 pu++;
pascal@12756	6265 }
pascal@12756	6266 }
pascal@12756	6267
pascal@12756	6268 /* filtering: simple convolution=inner products */
pascal@12756	6269
pascal@12756	6270 for (i=filterlength; i<dim1; i++) {
pascal@12756	6271
pascal@12756	6272
pascal@12756	6273
pascal@12756	6274 Andersen, et al. Experimental [Page 112]
pascal@12756	6275
pascal@12756	6276 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6277
pascal@12756	6278
pascal@12756	6279 for (j=0;j<ENH_UPS0; j++){
pascal@12756	6280 *pu=0.0;
pascal@12756	6281 pp = polyp[j];
pascal@12756	6282 ps = seq1+i;
pascal@12756	6283 for (k=0; k<filterlength; k++) {
pascal@12756	6284 pu += ps-- * *pp++;
pascal@12756	6285 }
pascal@12756	6286 pu++;
pascal@12756	6287 }
pascal@12756	6288 }
pascal@12756	6289
pascal@12756	6290 /* filtering: filter overhangs right side of sequence */
pascal@12756	6291
pascal@12756	6292 for (q=1; q<=hfl; q++) {
pascal@12756	6293 for (j=0; j<ENH_UPS0; j++) {
pascal@12756	6294 *pu=0.0;
pascal@12756	6295 pp = polyp[j]+q;
pascal@12756	6296 ps = seq1+dim1-1;
pascal@12756	6297 for (k=0; k<filterlength-q; k++) {
pascal@12756	6298 pu += ps-- * *pp++;
pascal@12756	6299 }
pascal@12756	6300 pu++;
pascal@12756	6301 }
pascal@12756	6302 }
pascal@12756	6303 }
pascal@12756	6304
pascal@12756	6305
pascal@12756	6306 /----------------------------------------------------------------
pascal@12756	6307 * find segment starting near idata+estSegPos that has highest
pascal@12756	6308 * correlation with idata+centerStartPos through
pascal@12756	6309 * idata+centerStartPos+ENH_BLOCKL-1 segment is found at a
pascal@12756	6310 * resolution of ENH_UPSO times the original of the original
pascal@12756	6311 * sampling rate
pascal@12756	6312 ---------------------------------------------------------------/
pascal@12756	6313
pascal@12756	6314 void refiner(
pascal@12756	6315 float seg, / (o) segment array */
pascal@12756	6316 float updStartPos, / (o) updated start point */
pascal@12756	6317 float* idata, /* (i) original data buffer */
pascal@12756	6318 int idatal, /* (i) dimension of idata */
pascal@12756	6319 int centerStartPos, /* (i) beginning center segment */
pascal@12756	6320 float estSegPos,/* (i) estimated beginning other segment */
pascal@12756	6321 float period /* (i) estimated pitch period */
pascal@12756	6322 ){
pascal@12756	6323 int estSegPosRounded,searchSegStartPos,searchSegEndPos,corrdim;
pascal@12756	6324 int tloc,tloc2,i,st,en,fraction;
pascal@12756	6325 float vect[ENH_VECTL],corrVec[ENH_CORRDIM],maxv;
pascal@12756	6326 float corrVecUps[ENH_CORRDIM*ENH_UPS0];
pascal@12756	6327
pascal@12756	6328
pascal@12756	6329
pascal@12756	6330 Andersen, et al. Experimental [Page 113]
pascal@12756	6331
pascal@12756	6332 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6333
pascal@12756	6334
pascal@12756	6335 /* defining array bounds */
pascal@12756	6336
pascal@12756	6337 estSegPosRounded=(int)(estSegPos - 0.5);
pascal@12756	6338
pascal@12756	6339 searchSegStartPos=estSegPosRounded-ENH_SLOP;
pascal@12756	6340
pascal@12756	6341 if (searchSegStartPos<0) {
pascal@12756	6342 searchSegStartPos=0;
pascal@12756	6343 }
pascal@12756	6344 searchSegEndPos=estSegPosRounded+ENH_SLOP;
pascal@12756	6345
pascal@12756	6346 if (searchSegEndPos+ENH_BLOCKL >= idatal) {
pascal@12756	6347 searchSegEndPos=idatal-ENH_BLOCKL-1;
pascal@12756	6348 }
pascal@12756	6349 corrdim=searchSegEndPos-searchSegStartPos+1;
pascal@12756	6350
pascal@12756	6351 /* compute upsampled correlation (corr33) and find
pascal@12756	6352 location of max */
pascal@12756	6353
pascal@12756	6354 mycorr1(corrVec,idata+searchSegStartPos,
pascal@12756	6355 corrdim+ENH_BLOCKL-1,idata+centerStartPos,ENH_BLOCKL);
pascal@12756	6356 enh_upsample(corrVecUps,corrVec,corrdim,ENH_FL0);
pascal@12756	6357 tloc=0; maxv=corrVecUps[0];
pascal@12756	6358 for (i=1; i<ENH_UPS0*corrdim; i++) {
pascal@12756	6359
pascal@12756	6360 if (corrVecUps[i]>maxv) {
pascal@12756	6361 tloc=i;
pascal@12756	6362 maxv=corrVecUps[i];
pascal@12756	6363 }
pascal@12756	6364 }
pascal@12756	6365
pascal@12756	6366 /* make vector can be upsampled without ever running outside
pascal@12756	6367 bounds */
pascal@12756	6368
pascal@12756	6369 *updStartPos= (float)searchSegStartPos +
pascal@12756	6370 (float)tloc/(float)ENH_UPS0+(float)1.0;
pascal@12756	6371 tloc2=(int)(tloc/ENH_UPS0);
pascal@12756	6372
pascal@12756	6373 if (tloc>tloc2*ENH_UPS0) {
pascal@12756	6374 tloc2++;
pascal@12756	6375 }
pascal@12756	6376 st=searchSegStartPos+tloc2-ENH_FL0;
pascal@12756	6377
pascal@12756	6378 if (st<0) {
pascal@12756	6379 memset(vect,0,-st*sizeof(float));
pascal@12756	6380 memcpy(&vect[-st],idata, (ENH_VECTL+st)*sizeof(float));
pascal@12756	6381 }
pascal@12756	6382 else {
pascal@12756	6383
pascal@12756	6384
pascal@12756	6385
pascal@12756	6386 Andersen, et al. Experimental [Page 114]
pascal@12756	6387
pascal@12756	6388 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6389
pascal@12756	6390
pascal@12756	6391 en=st+ENH_VECTL;
pascal@12756	6392
pascal@12756	6393 if (en>idatal) {
pascal@12756	6394 memcpy(vect, &idata[st],
pascal@12756	6395 (ENH_VECTL-(en-idatal))*sizeof(float));
pascal@12756	6396 memset(&vect[ENH_VECTL-(en-idatal)], 0,
pascal@12756	6397 (en-idatal)*sizeof(float));
pascal@12756	6398 }
pascal@12756	6399 else {
pascal@12756	6400 memcpy(vect, &idata[st], ENH_VECTL*sizeof(float));
pascal@12756	6401 }
pascal@12756	6402 }
pascal@12756	6403 fraction=tloc2*ENH_UPS0-tloc;
pascal@12756	6404
pascal@12756	6405 /* compute the segment (this is actually a convolution) */
pascal@12756	6406
pascal@12756	6407 mycorr1(seg,vect,ENH_VECTL,polyphaserTbl+(2ENH_FL0+1)fraction,
pascal@12756	6408 2*ENH_FL0+1);
pascal@12756	6409 }
pascal@12756	6410
pascal@12756	6411 /----------------------------------------------------------------
pascal@12756	6412 * find the smoothed output data
pascal@12756	6413 ---------------------------------------------------------------/
pascal@12756	6414
pascal@12756	6415 void smath(
pascal@12756	6416 float odata, / (o) smoothed output */
pascal@12756	6417 float sseq,/ (i) said second sequence of waveforms */
pascal@12756	6418 int hl, /* (i) 2hl+1 is sseq dimension /
pascal@12756	6419 float alpha0/* (i) max smoothing energy fraction */
pascal@12756	6420 ){
pascal@12756	6421 int i,k;
pascal@12756	6422 float w00,w10,w11,A,B,C,*psseq,err,errs;
pascal@12756	6423 float surround[BLOCKL_MAX]; /* shape contributed by other than
pascal@12756	6424 current */
pascal@12756	6425 float wt[2ENH_HL+1]; / waveform weighting to get
pascal@12756	6426 surround shape */
pascal@12756	6427 float denom;
pascal@12756	6428
pascal@12756	6429 /* create shape of contribution from all waveforms except the
pascal@12756	6430 current one */
pascal@12756	6431
pascal@12756	6432 for (i=1; i<=2*hl+1; i++) {
pascal@12756	6433 wt[i-1] = (float)0.5(1 - (float)cos(2PIi/(2hl+2)));
pascal@12756	6434 }
pascal@12756	6435 wt[hl]=0.0; /* for clarity, not used */
pascal@12756	6436 for (i=0; i<ENH_BLOCKL; i++) {
pascal@12756	6437 surround[i]=sseq[i]*wt[0];
pascal@12756	6438 }
pascal@12756	6439
pascal@12756	6440
pascal@12756	6441
pascal@12756	6442 Andersen, et al. Experimental [Page 115]
pascal@12756	6443
pascal@12756	6444 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6445
pascal@12756	6446
pascal@12756	6447 for (k=1; k<hl; k++) {
pascal@12756	6448 psseq=sseq+k*ENH_BLOCKL;
pascal@12756	6449 for(i=0;i<ENH_BLOCKL; i++) {
pascal@12756	6450 surround[i]+=psseq[i]*wt[k];
pascal@12756	6451 }
pascal@12756	6452 }
pascal@12756	6453 for (k=hl+1; k<=2*hl; k++) {
pascal@12756	6454 psseq=sseq+k*ENH_BLOCKL;
pascal@12756	6455 for(i=0;i<ENH_BLOCKL; i++) {
pascal@12756	6456 surround[i]+=psseq[i]*wt[k];
pascal@12756	6457 }
pascal@12756	6458 }
pascal@12756	6459
pascal@12756	6460 /* compute some inner products */
pascal@12756	6461
pascal@12756	6462 w00 = w10 = w11 = 0.0;
pascal@12756	6463 psseq=sseq+hlENH_BLOCKL; / current block */
pascal@12756	6464 for (i=0; i<ENH_BLOCKL;i++) {
pascal@12756	6465 w00+=psseq[i]*psseq[i];
pascal@12756	6466 w11+=surround[i]*surround[i];
pascal@12756	6467 w10+=surround[i]*psseq[i];
pascal@12756	6468 }
pascal@12756	6469
pascal@12756	6470 if (fabs(w11) < 1.0) {
pascal@12756	6471 w11=1.0;
pascal@12756	6472 }
pascal@12756	6473 C = (float)sqrt( w00/w11);
pascal@12756	6474
pascal@12756	6475 /* first try enhancement without power-constraint */
pascal@12756	6476
pascal@12756	6477 errs=0.0;
pascal@12756	6478 psseq=sseq+hl*ENH_BLOCKL;
pascal@12756	6479 for (i=0; i<ENH_BLOCKL; i++) {
pascal@12756	6480 odata[i]=C*surround[i];
pascal@12756	6481 err=psseq[i]-odata[i];
pascal@12756	6482 errs+=err*err;
pascal@12756	6483 }
pascal@12756	6484
pascal@12756	6485 /* if constraint violated by first try, add constraint */
pascal@12756	6486
pascal@12756	6487 if (errs > alpha0 * w00) {
pascal@12756	6488 if ( w00 < 1) {
pascal@12756	6489 w00=1;
pascal@12756	6490 }
pascal@12756	6491 denom = (w11w00-w10w10)/(w00*w00);
pascal@12756	6492
pascal@12756	6493 if (denom > 0.0001) { /* eliminates numerical problems
pascal@12756	6494 for if smooth */
pascal@12756	6495
pascal@12756	6496
pascal@12756	6497
pascal@12756	6498 Andersen, et al. Experimental [Page 116]
pascal@12756	6499
pascal@12756	6500 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6501
pascal@12756	6502
pascal@12756	6503 A = (float)sqrt( (alpha0- alpha0*alpha0/4)/denom);
pascal@12756	6504 B = -alpha0/2 - A * w10/w00;
pascal@12756	6505 B = B+1;
pascal@12756	6506 }
pascal@12756	6507 else { /* essentially no difference between cycles;
pascal@12756	6508 smoothing not needed */
pascal@12756	6509 A= 0.0;
pascal@12756	6510 B= 1.0;
pascal@12756	6511 }
pascal@12756	6512
pascal@12756	6513 /* create smoothed sequence */
pascal@12756	6514
pascal@12756	6515 psseq=sseq+hl*ENH_BLOCKL;
pascal@12756	6516 for (i=0; i<ENH_BLOCKL; i++) {
pascal@12756	6517 odata[i]=Asurround[i]+Bpsseq[i];
pascal@12756	6518 }
pascal@12756	6519 }
pascal@12756	6520 }
pascal@12756	6521
pascal@12756	6522 /----------------------------------------------------------------
pascal@12756	6523 * get the pitch-synchronous sample sequence
pascal@12756	6524 ---------------------------------------------------------------/
pascal@12756	6525
pascal@12756	6526 void getsseq(
pascal@12756	6527 float sseq, / (o) the pitch-synchronous sequence */
pascal@12756	6528 float idata, / (i) original data */
pascal@12756	6529 int idatal, /* (i) dimension of data */
pascal@12756	6530 int centerStartPos, /* (i) where current block starts */
pascal@12756	6531 float period, / (i) rough-pitch-period array */
pascal@12756	6532 float plocs, / (i) where periods of period array
pascal@12756	6533 are taken */
pascal@12756	6534 int periodl, /* (i) dimension period array */
pascal@12756	6535 int hl /* (i) 2hl+1 is the number of sequences /
pascal@12756	6536 ){
pascal@12756	6537 int i,centerEndPos,q;
pascal@12756	6538 float blockStartPos[2*ENH_HL+1];
pascal@12756	6539 int lagBlock[2*ENH_HL+1];
pascal@12756	6540 float plocs2[ENH_PLOCSL];
pascal@12756	6541 float *psseq;
pascal@12756	6542
pascal@12756	6543 centerEndPos=centerStartPos+ENH_BLOCKL-1;
pascal@12756	6544
pascal@12756	6545 /* present */
pascal@12756	6546
pascal@12756	6547 NearestNeighbor(lagBlock+hl,plocs,
pascal@12756	6548 (float)0.5*(centerStartPos+centerEndPos),periodl);
pascal@12756	6549
pascal@12756	6550 blockStartPos[hl]=(float)centerStartPos;
pascal@12756	6551
pascal@12756	6552
pascal@12756	6553
pascal@12756	6554 Andersen, et al. Experimental [Page 117]
pascal@12756	6555
pascal@12756	6556 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6557
pascal@12756	6558
pascal@12756	6559 psseq=sseq+ENH_BLOCKL*hl;
pascal@12756	6560 memcpy(psseq, idata+centerStartPos, ENH_BLOCKL*sizeof(float));
pascal@12756	6561
pascal@12756	6562 /* past */
pascal@12756	6563
pascal@12756	6564 for (q=hl-1; q>=0; q--) {
pascal@12756	6565 blockStartPos[q]=blockStartPos[q+1]-period[lagBlock[q+1]];
pascal@12756	6566 NearestNeighbor(lagBlock+q,plocs,
pascal@12756	6567 blockStartPos[q]+
pascal@12756	6568 ENH_BLOCKL_HALF-period[lagBlock[q+1]], periodl);
pascal@12756	6569
pascal@12756	6570
pascal@12756	6571 if (blockStartPos[q]-ENH_OVERHANG>=0) {
pascal@12756	6572 refiner(sseq+q*ENH_BLOCKL, blockStartPos+q, idata,
pascal@12756	6573 idatal, centerStartPos, blockStartPos[q],
pascal@12756	6574 period[lagBlock[q+1]]);
pascal@12756	6575 } else {
pascal@12756	6576 psseq=sseq+q*ENH_BLOCKL;
pascal@12756	6577 memset(psseq, 0, ENH_BLOCKL*sizeof(float));
pascal@12756	6578 }
pascal@12756	6579 }
pascal@12756	6580
pascal@12756	6581 /* future */
pascal@12756	6582
pascal@12756	6583 for (i=0; i<periodl; i++) {
pascal@12756	6584 plocs2[i]=plocs[i]-period[i];
pascal@12756	6585 }
pascal@12756	6586 for (q=hl+1; q<=2*hl; q++) {
pascal@12756	6587 NearestNeighbor(lagBlock+q,plocs2,
pascal@12756	6588 blockStartPos[q-1]+ENH_BLOCKL_HALF,periodl);
pascal@12756	6589
pascal@12756	6590 blockStartPos[q]=blockStartPos[q-1]+period[lagBlock[q]];
pascal@12756	6591 if (blockStartPos[q]+ENH_BLOCKL+ENH_OVERHANG<idatal) {
pascal@12756	6592 refiner(sseq+ENH_BLOCKL*q, blockStartPos+q, idata,
pascal@12756	6593 idatal, centerStartPos, blockStartPos[q],
pascal@12756	6594 period[lagBlock[q]]);
pascal@12756	6595 }
pascal@12756	6596 else {
pascal@12756	6597 psseq=sseq+q*ENH_BLOCKL;
pascal@12756	6598 memset(psseq, 0, ENH_BLOCKL*sizeof(float));
pascal@12756	6599 }
pascal@12756	6600 }
pascal@12756	6601 }
pascal@12756	6602
pascal@12756	6603 /----------------------------------------------------------------
pascal@12756	6604 * perform enhancement on idata+centerStartPos through
pascal@12756	6605 * idata+centerStartPos+ENH_BLOCKL-1
pascal@12756	6606 ---------------------------------------------------------------/
pascal@12756	6607
pascal@12756	6608
pascal@12756	6609
pascal@12756	6610 Andersen, et al. Experimental [Page 118]
pascal@12756	6611
pascal@12756	6612 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6613
pascal@12756	6614
pascal@12756	6615 void enhancer(
pascal@12756	6616 float odata, / (o) smoothed block, dimension blockl */
pascal@12756	6617 float idata, / (i) data buffer used for enhancing */
pascal@12756	6618 int idatal, /* (i) dimension idata */
pascal@12756	6619 int centerStartPos, /* (i) first sample current block
pascal@12756	6620 within idata */
pascal@12756	6621 float alpha0, /* (i) max correction-energy-fraction
pascal@12756	6622 (in [0,1]) */
pascal@12756	6623 float period, / (i) pitch period array */
pascal@12756	6624 float plocs, / (i) locations where period array
pascal@12756	6625 values valid */
pascal@12756	6626 int periodl /* (i) dimension of period and plocs */
pascal@12756	6627 ){
pascal@12756	6628 float sseq[(2ENH_HL+1)ENH_BLOCKL];
pascal@12756	6629
pascal@12756	6630 /* get said second sequence of segments */
pascal@12756	6631
pascal@12756	6632 getsseq(sseq,idata,idatal,centerStartPos,period,
pascal@12756	6633 plocs,periodl,ENH_HL);
pascal@12756	6634
pascal@12756	6635 /* compute the smoothed output from said second sequence */
pascal@12756	6636
pascal@12756	6637 smath(odata,sseq,ENH_HL,alpha0);
pascal@12756	6638
pascal@12756	6639 }
pascal@12756	6640
pascal@12756	6641 /----------------------------------------------------------------
pascal@12756	6642 * cross correlation
pascal@12756	6643 ---------------------------------------------------------------/
pascal@12756	6644
pascal@12756	6645 float xCorrCoef(
pascal@12756	6646 float target, / (i) first array */
pascal@12756	6647 float regressor, / (i) second array */
pascal@12756	6648 int subl /* (i) dimension arrays */
pascal@12756	6649 ){
pascal@12756	6650 int i;
pascal@12756	6651 float ftmp1, ftmp2;
pascal@12756	6652
pascal@12756	6653 ftmp1 = 0.0;
pascal@12756	6654 ftmp2 = 0.0;
pascal@12756	6655 for (i=0; i<subl; i++) {
pascal@12756	6656 ftmp1 += target[i]*regressor[i];
pascal@12756	6657 ftmp2 += regressor[i]*regressor[i];
pascal@12756	6658 }
pascal@12756	6659
pascal@12756	6660 if (ftmp1 > 0.0) {
pascal@12756	6661 return (float)(ftmp1*ftmp1/ftmp2);
pascal@12756	6662 }
pascal@12756	6663
pascal@12756	6664
pascal@12756	6665
pascal@12756	6666 Andersen, et al. Experimental [Page 119]
pascal@12756	6667
pascal@12756	6668 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6669
pascal@12756	6670
pascal@12756	6671 else {
pascal@12756	6672 return (float)0.0;
pascal@12756	6673 }
pascal@12756	6674 }
pascal@12756	6675
pascal@12756	6676 /----------------------------------------------------------------
pascal@12756	6677 * interface for enhancer
pascal@12756	6678 ---------------------------------------------------------------/
pascal@12756	6679
pascal@12756	6680 int enhancerInterface(
pascal@12756	6681 float out, / (o) enhanced signal */
pascal@12756	6682 float in, / (i) unenhanced signal */
pascal@12756	6683 iLBC_Dec_Inst_t iLBCdec_inst / (i) buffers etc */
pascal@12756	6684 ){
pascal@12756	6685 float enh_buf, enh_period;
pascal@12756	6686 int iblock, isample;
pascal@12756	6687 int lag=0, ilag, i, ioffset;
pascal@12756	6688 float cc, maxcc;
pascal@12756	6689 float ftmp1, ftmp2;
pascal@12756	6690 float inPtr, enh_bufPtr1, *enh_bufPtr2;
pascal@12756	6691 float plc_pred[ENH_BLOCKL];
pascal@12756	6692
pascal@12756	6693 float lpState[6], downsampled[(ENH_NBLOCKS*ENH_BLOCKL+120)/2];
pascal@12756	6694 int inLen=ENH_NBLOCKS*ENH_BLOCKL+120;
pascal@12756	6695 int start, plc_blockl, inlag;
pascal@12756	6696
pascal@12756	6697 enh_buf=iLBCdec_inst->enh_buf;
pascal@12756	6698 enh_period=iLBCdec_inst->enh_period;
pascal@12756	6699
pascal@12756	6700 memmove(enh_buf, &enh_buf[iLBCdec_inst->blockl],
pascal@12756	6701 (ENH_BUFL-iLBCdec_inst->blockl)*sizeof(float));
pascal@12756	6702
pascal@12756	6703 memcpy(&enh_buf[ENH_BUFL-iLBCdec_inst->blockl], in,
pascal@12756	6704 iLBCdec_inst->blockl*sizeof(float));
pascal@12756	6705
pascal@12756	6706 if (iLBCdec_inst->mode==30)
pascal@12756	6707 plc_blockl=ENH_BLOCKL;
pascal@12756	6708 else
pascal@12756	6709 plc_blockl=40;
pascal@12756	6710
pascal@12756	6711 /* when 20 ms frame, move processing one block */
pascal@12756	6712 ioffset=0;
pascal@12756	6713 if (iLBCdec_inst->mode==20) ioffset=1;
pascal@12756	6714
pascal@12756	6715 i=3-ioffset;
pascal@12756	6716 memmove(enh_period, &enh_period[i],
pascal@12756	6717 (ENH_NBLOCKS_TOT-i)*sizeof(float));
pascal@12756	6718
pascal@12756	6719
pascal@12756	6720
pascal@12756	6721
pascal@12756	6722 Andersen, et al. Experimental [Page 120]
pascal@12756	6723
pascal@12756	6724 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6725
pascal@12756	6726
pascal@12756	6727 /* Set state information to the 6 samples right before
pascal@12756	6728 the samples to be downsampled. */
pascal@12756	6729
pascal@12756	6730 memcpy(lpState,
pascal@12756	6731 enh_buf+(ENH_NBLOCKS_EXTRA+ioffset)*ENH_BLOCKL-126,
pascal@12756	6732 6*sizeof(float));
pascal@12756	6733
pascal@12756	6734 /* Down sample a factor 2 to save computations */
pascal@12756	6735
pascal@12756	6736 DownSample(enh_buf+(ENH_NBLOCKS_EXTRA+ioffset)*ENH_BLOCKL-120,
pascal@12756	6737 lpFilt_coefsTbl, inLen-ioffset*ENH_BLOCKL,
pascal@12756	6738 lpState, downsampled);
pascal@12756	6739
pascal@12756	6740 /* Estimate the pitch in the down sampled domain. */
pascal@12756	6741 for (iblock = 0; iblock<ENH_NBLOCKS-ioffset; iblock++) {
pascal@12756	6742
pascal@12756	6743 lag = 10;
pascal@12756	6744 maxcc = xCorrCoef(downsampled+60+iblock*
pascal@12756	6745 ENH_BLOCKL_HALF, downsampled+60+iblock*
pascal@12756	6746 ENH_BLOCKL_HALF-lag, ENH_BLOCKL_HALF);
pascal@12756	6747 for (ilag=11; ilag<60; ilag++) {
pascal@12756	6748 cc = xCorrCoef(downsampled+60+iblock*
pascal@12756	6749 ENH_BLOCKL_HALF, downsampled+60+iblock*
pascal@12756	6750 ENH_BLOCKL_HALF-ilag, ENH_BLOCKL_HALF);
pascal@12756	6751
pascal@12756	6752 if (cc > maxcc) {
pascal@12756	6753 maxcc = cc;
pascal@12756	6754 lag = ilag;
pascal@12756	6755 }
pascal@12756	6756 }
pascal@12756	6757
pascal@12756	6758 /* Store the estimated lag in the non-downsampled domain */
pascal@12756	6759 enh_period[iblock+ENH_NBLOCKS_EXTRA+ioffset] = (float)lag*2;
pascal@12756	6760
pascal@12756	6761
pascal@12756	6762 }
pascal@12756	6763
pascal@12756	6764
pascal@12756	6765 /* PLC was performed on the previous packet */
pascal@12756	6766 if (iLBCdec_inst->prev_enh_pl==1) {
pascal@12756	6767
pascal@12756	6768 inlag=(int)enh_period[ENH_NBLOCKS_EXTRA+ioffset];
pascal@12756	6769
pascal@12756	6770 lag = inlag-1;
pascal@12756	6771 maxcc = xCorrCoef(in, in+lag, plc_blockl);
pascal@12756	6772 for (ilag=inlag; ilag<=inlag+1; ilag++) {
pascal@12756	6773 cc = xCorrCoef(in, in+ilag, plc_blockl);
pascal@12756	6774
pascal@12756	6775
pascal@12756	6776
pascal@12756	6777
pascal@12756	6778 Andersen, et al. Experimental [Page 121]
pascal@12756	6779
pascal@12756	6780 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6781
pascal@12756	6782
pascal@12756	6783 if (cc > maxcc) {
pascal@12756	6784 maxcc = cc;
pascal@12756	6785 lag = ilag;
pascal@12756	6786 }
pascal@12756	6787 }
pascal@12756	6788
pascal@12756	6789 enh_period[ENH_NBLOCKS_EXTRA+ioffset-1]=(float)lag;
pascal@12756	6790
pascal@12756	6791 /* compute new concealed residual for the old lookahead,
pascal@12756	6792 mix the forward PLC with a backward PLC from
pascal@12756	6793 the new frame */
pascal@12756	6794
pascal@12756	6795 inPtr=&in[lag-1];
pascal@12756	6796
pascal@12756	6797 enh_bufPtr1=&plc_pred[plc_blockl-1];
pascal@12756	6798
pascal@12756	6799 if (lag>plc_blockl) {
pascal@12756	6800 start=plc_blockl;
pascal@12756	6801 } else {
pascal@12756	6802 start=lag;
pascal@12756	6803 }
pascal@12756	6804
pascal@12756	6805 for (isample = start; isample>0; isample--) {
pascal@12756	6806 enh_bufPtr1-- = inPtr--;
pascal@12756	6807 }
pascal@12756	6808
pascal@12756	6809 enh_bufPtr2=&enh_buf[ENH_BUFL-1-iLBCdec_inst->blockl];
pascal@12756	6810 for (isample = (plc_blockl-1-lag); isample>=0; isample--) {
pascal@12756	6811 enh_bufPtr1-- = enh_bufPtr2--;
pascal@12756	6812 }
pascal@12756	6813
pascal@12756	6814 /* limit energy change */
pascal@12756	6815 ftmp2=0.0;
pascal@12756	6816 ftmp1=0.0;
pascal@12756	6817 for (i=0;i<plc_blockl;i++) {
pascal@12756	6818 ftmp2+=enh_buf[ENH_BUFL-1-iLBCdec_inst->blockl-i]*
pascal@12756	6819 enh_buf[ENH_BUFL-1-iLBCdec_inst->blockl-i];
pascal@12756	6820 ftmp1+=plc_pred[i]*plc_pred[i];
pascal@12756	6821 }
pascal@12756	6822 ftmp1=(float)sqrt(ftmp1/(float)plc_blockl);
pascal@12756	6823 ftmp2=(float)sqrt(ftmp2/(float)plc_blockl);
pascal@12756	6824 if (ftmp1>(float)2.0*ftmp2 && ftmp1>0.0) {
pascal@12756	6825 for (i=0;i<plc_blockl-10;i++) {
pascal@12756	6826 plc_pred[i]=(float)2.0ftmp2/ftmp1;
pascal@12756	6827 }
pascal@12756	6828 for (i=plc_blockl-10;i<plc_blockl;i++) {
pascal@12756	6829 plc_pred[i]=(float)(i-plc_blockl+10)
pascal@12756	6830 ((float)1.0-(float)2.0*ftmp2/ftmp1)/(float)(10)+
pascal@12756	6831
pascal@12756	6832
pascal@12756	6833
pascal@12756	6834 Andersen, et al. Experimental [Page 122]
pascal@12756	6835
pascal@12756	6836 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6837
pascal@12756	6838
pascal@12756	6839 (float)2.0*ftmp2/ftmp1;
pascal@12756	6840 }
pascal@12756	6841 }
pascal@12756	6842
pascal@12756	6843 enh_bufPtr1=&enh_buf[ENH_BUFL-1-iLBCdec_inst->blockl];
pascal@12756	6844 for (i=0; i<plc_blockl; i++) {
pascal@12756	6845 ftmp1 = (float) (i+1) / (float) (plc_blockl+1);
pascal@12756	6846 enh_bufPtr1 = ftmp1;
pascal@12756	6847 enh_bufPtr1 += ((float)1.0-ftmp1)
pascal@12756	6848 plc_pred[plc_blockl-1-i];
pascal@12756	6849 enh_bufPtr1--;
pascal@12756	6850 }
pascal@12756	6851 }
pascal@12756	6852
pascal@12756	6853 if (iLBCdec_inst->mode==20) {
pascal@12756	6854 /* Enhancer with 40 samples delay */
pascal@12756	6855 for (iblock = 0; iblock<2; iblock++) {
pascal@12756	6856 enhancer(out+iblock*ENH_BLOCKL, enh_buf,
pascal@12756	6857 ENH_BUFL, (5+iblock)*ENH_BLOCKL+40,
pascal@12756	6858 ENH_ALPHA0, enh_period, enh_plocsTbl,
pascal@12756	6859 ENH_NBLOCKS_TOT);
pascal@12756	6860 }
pascal@12756	6861 } else if (iLBCdec_inst->mode==30) {
pascal@12756	6862 /* Enhancer with 80 samples delay */
pascal@12756	6863 for (iblock = 0; iblock<3; iblock++) {
pascal@12756	6864 enhancer(out+iblock*ENH_BLOCKL, enh_buf,
pascal@12756	6865 ENH_BUFL, (4+iblock)*ENH_BLOCKL,
pascal@12756	6866 ENH_ALPHA0, enh_period, enh_plocsTbl,
pascal@12756	6867 ENH_NBLOCKS_TOT);
pascal@12756	6868 }
pascal@12756	6869 }
pascal@12756	6870
pascal@12756	6871 return (lag*2);
pascal@12756	6872 }
pascal@12756	6873
pascal@12756	6874 A.17. filter.h
pascal@12756	6875
pascal@12756	6876 /******************************************************************
pascal@12756	6877
pascal@12756	6878 iLBC Speech Coder ANSI-C Source Code
pascal@12756	6879
pascal@12756	6880 filter.h
pascal@12756	6881
pascal@12756	6882 Copyright (C) The Internet Society (2004).
pascal@12756	6883 All Rights Reserved.
pascal@12756	6884
pascal@12756	6885 ******************************************************************/
pascal@12756	6886
pascal@12756	6887
pascal@12756	6888
pascal@12756	6889
pascal@12756	6890 Andersen, et al. Experimental [Page 123]
pascal@12756	6891
pascal@12756	6892 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6893
pascal@12756	6894
pascal@12756	6895 #ifndef __iLBC_FILTER_H
pascal@12756	6896 #define __iLBC_FILTER_H
pascal@12756	6897
pascal@12756	6898 void AllPoleFilter(
pascal@12756	6899 float InOut, / (i/o) on entrance InOut[-orderCoef] to
pascal@12756	6900 InOut[-1] contain the state of the
pascal@12756	6901 filter (delayed samples). InOut[0] to
pascal@12756	6902 InOut[lengthInOut-1] contain the filter
pascal@12756	6903 input, on en exit InOut[-orderCoef] to
pascal@12756	6904 InOut[-1] is unchanged and InOut[0] to
pascal@12756	6905 InOut[lengthInOut-1] contain filtered
pascal@12756	6906 samples */
pascal@12756	6907 float Coef,/ (i) filter coefficients, Coef[0] is assumed
pascal@12756	6908 to be 1.0 */
pascal@12756	6909 int lengthInOut,/* (i) number of input/output samples */
pascal@12756	6910 int orderCoef /* (i) number of filter coefficients */
pascal@12756	6911 );
pascal@12756	6912
pascal@12756	6913 void AllZeroFilter(
pascal@12756	6914 float In, / (i) In[0] to In[lengthInOut-1] contain
pascal@12756	6915 filter input samples */
pascal@12756	6916 float Coef,/ (i) filter coefficients (Coef[0] is assumed
pascal@12756	6917 to be 1.0) */
pascal@12756	6918 int lengthInOut,/* (i) number of input/output samples */
pascal@12756	6919 int orderCoef, /* (i) number of filter coefficients */
pascal@12756	6920 float Out / (i/o) on entrance Out[-orderCoef] to Out[-1]
pascal@12756	6921 contain the filter state, on exit Out[0]
pascal@12756	6922 to Out[lengthInOut-1] contain filtered
pascal@12756	6923 samples */
pascal@12756	6924 );
pascal@12756	6925
pascal@12756	6926 void ZeroPoleFilter(
pascal@12756	6927 float In, / (i) In[0] to In[lengthInOut-1] contain filter
pascal@12756	6928 input samples In[-orderCoef] to In[-1]
pascal@12756	6929 contain state of all-zero section */
pascal@12756	6930 float ZeroCoef,/ (i) filter coefficients for all-zero
pascal@12756	6931 section (ZeroCoef[0] is assumed to
pascal@12756	6932 be 1.0) */
pascal@12756	6933 float PoleCoef,/ (i) filter coefficients for all-pole section
pascal@12756	6934 (ZeroCoef[0] is assumed to be 1.0) */
pascal@12756	6935 int lengthInOut,/* (i) number of input/output samples */
pascal@12756	6936 int orderCoef, /* (i) number of filter coefficients */
pascal@12756	6937 float Out / (i/o) on entrance Out[-orderCoef] to Out[-1]
pascal@12756	6938 contain state of all-pole section. On
pascal@12756	6939 exit Out[0] to Out[lengthInOut-1]
pascal@12756	6940 contain filtered samples */
pascal@12756	6941 );
pascal@12756	6942
pascal@12756	6943
pascal@12756	6944
pascal@12756	6945
pascal@12756	6946 Andersen, et al. Experimental [Page 124]
pascal@12756	6947
pascal@12756	6948 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	6949
pascal@12756	6950
pascal@12756	6951 void DownSample (
pascal@12756	6952 float In, / (i) input samples */
pascal@12756	6953 float Coef, / (i) filter coefficients */
pascal@12756	6954 int lengthIn, /* (i) number of input samples */
pascal@12756	6955 float state, / (i) filter state */
pascal@12756	6956 float Out / (o) downsampled output */
pascal@12756	6957 );
pascal@12756	6958
pascal@12756	6959 #endif
pascal@12756	6960
pascal@12756	6961 A.18. filter.c
pascal@12756	6962
pascal@12756	6963 /******************************************************************
pascal@12756	6964
pascal@12756	6965 iLBC Speech Coder ANSI-C Source Code
pascal@12756	6966
pascal@12756	6967 filter.c
pascal@12756	6968
pascal@12756	6969 Copyright (C) The Internet Society (2004).
pascal@12756	6970 All Rights Reserved.
pascal@12756	6971
pascal@12756	6972 ******************************************************************/
pascal@12756	6973
pascal@12756	6974 #include "iLBC_define.h"
pascal@12756	6975
pascal@12756	6976 /----------------------------------------------------------------
pascal@12756	6977 * all-pole filter
pascal@12756	6978 ---------------------------------------------------------------/
pascal@12756	6979
pascal@12756	6980 void AllPoleFilter(
pascal@12756	6981 float InOut, / (i/o) on entrance InOut[-orderCoef] to
pascal@12756	6982 InOut[-1] contain the state of the
pascal@12756	6983 filter (delayed samples). InOut[0] to
pascal@12756	6984 InOut[lengthInOut-1] contain the filter
pascal@12756	6985 input, on en exit InOut[-orderCoef] to
pascal@12756	6986 InOut[-1] is unchanged and InOut[0] to
pascal@12756	6987 InOut[lengthInOut-1] contain filtered
pascal@12756	6988 samples */
pascal@12756	6989 float Coef,/ (i) filter coefficients, Coef[0] is assumed
pascal@12756	6990 to be 1.0 */
pascal@12756	6991 int lengthInOut,/* (i) number of input/output samples */
pascal@12756	6992 int orderCoef /* (i) number of filter coefficients */
pascal@12756	6993 ){
pascal@12756	6994 int n,k;
pascal@12756	6995
pascal@12756	6996 for(n=0;n<lengthInOut;n++){
pascal@12756	6997 for(k=1;k<=orderCoef;k++){
pascal@12756	6998 InOut -= Coef[k]InOut[-k];
pascal@12756	6999
pascal@12756	7000
pascal@12756	7001
pascal@12756	7002 Andersen, et al. Experimental [Page 125]
pascal@12756	7003
pascal@12756	7004 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7005
pascal@12756	7006
pascal@12756	7007 }
pascal@12756	7008 InOut++;
pascal@12756	7009 }
pascal@12756	7010 }
pascal@12756	7011
pascal@12756	7012 /----------------------------------------------------------------
pascal@12756	7013 * all-zero filter
pascal@12756	7014 ---------------------------------------------------------------/
pascal@12756	7015
pascal@12756	7016 void AllZeroFilter(
pascal@12756	7017 float In, / (i) In[0] to In[lengthInOut-1] contain
pascal@12756	7018 filter input samples */
pascal@12756	7019 float Coef,/ (i) filter coefficients (Coef[0] is assumed
pascal@12756	7020 to be 1.0) */
pascal@12756	7021 int lengthInOut,/* (i) number of input/output samples */
pascal@12756	7022 int orderCoef, /* (i) number of filter coefficients */
pascal@12756	7023 float Out / (i/o) on entrance Out[-orderCoef] to Out[-1]
pascal@12756	7024 contain the filter state, on exit Out[0]
pascal@12756	7025 to Out[lengthInOut-1] contain filtered
pascal@12756	7026 samples */
pascal@12756	7027 ){
pascal@12756	7028 int n,k;
pascal@12756	7029
pascal@12756	7030 for(n=0;n<lengthInOut;n++){
pascal@12756	7031 Out = Coef[0]In[0];
pascal@12756	7032 for(k=1;k<=orderCoef;k++){
pascal@12756	7033 Out += Coef[k]In[-k];
pascal@12756	7034 }
pascal@12756	7035 Out++;
pascal@12756	7036 In++;
pascal@12756	7037 }
pascal@12756	7038 }
pascal@12756	7039
pascal@12756	7040 /----------------------------------------------------------------
pascal@12756	7041 * pole-zero filter
pascal@12756	7042 ---------------------------------------------------------------/
pascal@12756	7043
pascal@12756	7044 void ZeroPoleFilter(
pascal@12756	7045 float In, / (i) In[0] to In[lengthInOut-1] contain
pascal@12756	7046 filter input samples In[-orderCoef] to
pascal@12756	7047 In[-1] contain state of all-zero
pascal@12756	7048 section */
pascal@12756	7049 float ZeroCoef,/ (i) filter coefficients for all-zero
pascal@12756	7050 section (ZeroCoef[0] is assumed to
pascal@12756	7051 be 1.0) */
pascal@12756	7052 float PoleCoef,/ (i) filter coefficients for all-pole section
pascal@12756	7053 (ZeroCoef[0] is assumed to be 1.0) */
pascal@12756	7054 int lengthInOut,/* (i) number of input/output samples */
pascal@12756	7055
pascal@12756	7056
pascal@12756	7057
pascal@12756	7058 Andersen, et al. Experimental [Page 126]
pascal@12756	7059
pascal@12756	7060 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7061
pascal@12756	7062
pascal@12756	7063 int orderCoef, /* (i) number of filter coefficients */
pascal@12756	7064 float Out / (i/o) on entrance Out[-orderCoef] to Out[-1]
pascal@12756	7065 contain state of all-pole section. On
pascal@12756	7066 exit Out[0] to Out[lengthInOut-1]
pascal@12756	7067 contain filtered samples */
pascal@12756	7068 ){
pascal@12756	7069 AllZeroFilter(In,ZeroCoef,lengthInOut,orderCoef,Out);
pascal@12756	7070 AllPoleFilter(Out,PoleCoef,lengthInOut,orderCoef);
pascal@12756	7071 }
pascal@12756	7072
pascal@12756	7073 /----------------------------------------------------------------
pascal@12756	7074 * downsample (LP filter and decimation)
pascal@12756	7075 ---------------------------------------------------------------/
pascal@12756	7076
pascal@12756	7077 void DownSample (
pascal@12756	7078 float In, / (i) input samples */
pascal@12756	7079 float Coef, / (i) filter coefficients */
pascal@12756	7080 int lengthIn, /* (i) number of input samples */
pascal@12756	7081 float state, / (i) filter state */
pascal@12756	7082 float Out / (o) downsampled output */
pascal@12756	7083 ){
pascal@12756	7084 float o;
pascal@12756	7085 float *Out_ptr = Out;
pascal@12756	7086 float Coef_ptr, In_ptr;
pascal@12756	7087 float *state_ptr;
pascal@12756	7088 int i, j, stop;
pascal@12756	7089
pascal@12756	7090 /* LP filter and decimate at the same time */
pascal@12756	7091
pascal@12756	7092 for (i = DELAY_DS; i < lengthIn; i+=FACTOR_DS)
pascal@12756	7093 {
pascal@12756	7094 Coef_ptr = &Coef[0];
pascal@12756	7095 In_ptr = &In[i];
pascal@12756	7096 state_ptr = &state[FILTERORDER_DS-2];
pascal@12756	7097
pascal@12756	7098 o = (float)0.0;
pascal@12756	7099
pascal@12756	7100 stop = (i < FILTERORDER_DS) ? i + 1 : FILTERORDER_DS;
pascal@12756	7101
pascal@12756	7102 for (j = 0; j < stop; j++)
pascal@12756	7103 {
pascal@12756	7104 o += Coef_ptr++ (*In_ptr--);
pascal@12756	7105 }
pascal@12756	7106 for (j = i + 1; j < FILTERORDER_DS; j++)
pascal@12756	7107 {
pascal@12756	7108 o += Coef_ptr++ (*state_ptr--);
pascal@12756	7109 }
pascal@12756	7110
pascal@12756	7111
pascal@12756	7112
pascal@12756	7113
pascal@12756	7114 Andersen, et al. Experimental [Page 127]
pascal@12756	7115
pascal@12756	7116 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7117
pascal@12756	7118
pascal@12756	7119 *Out_ptr++ = o;
pascal@12756	7120 }
pascal@12756	7121
pascal@12756	7122 /* Get the last part (use zeros as input for the future) */
pascal@12756	7123
pascal@12756	7124 for (i=(lengthIn+FACTOR_DS); i<(lengthIn+DELAY_DS);
pascal@12756	7125 i+=FACTOR_DS) {
pascal@12756	7126
pascal@12756	7127 o=(float)0.0;
pascal@12756	7128
pascal@12756	7129 if (i<lengthIn) {
pascal@12756	7130 Coef_ptr = &Coef[0];
pascal@12756	7131 In_ptr = &In[i];
pascal@12756	7132 for (j=0; j<FILTERORDER_DS; j++) {
pascal@12756	7133 o += Coef_ptr++ (*Out_ptr--);
pascal@12756	7134 }
pascal@12756	7135 } else {
pascal@12756	7136 Coef_ptr = &Coef[i-lengthIn];
pascal@12756	7137 In_ptr = &In[lengthIn-1];
pascal@12756	7138 for (j=0; j<FILTERORDER_DS-(i-lengthIn); j++) {
pascal@12756	7139 o += Coef_ptr++ (*In_ptr--);
pascal@12756	7140 }
pascal@12756	7141 }
pascal@12756	7142 *Out_ptr++ = o;
pascal@12756	7143 }
pascal@12756	7144 }
pascal@12756	7145
pascal@12756	7146 A.19. FrameClassify.h
pascal@12756	7147
pascal@12756	7148 /******************************************************************
pascal@12756	7149
pascal@12756	7150 iLBC Speech Coder ANSI-C Source Code
pascal@12756	7151
pascal@12756	7152 FrameClassify.h
pascal@12756	7153
pascal@12756	7154 Copyright (C) The Internet Society (2004).
pascal@12756	7155 All Rights Reserved.
pascal@12756	7156
pascal@12756	7157 ******************************************************************/
pascal@12756	7158
pascal@12756	7159 #ifndef __iLBC_FRAMECLASSIFY_H
pascal@12756	7160 #define __iLBC_FRAMECLASSIFY_H
pascal@12756	7161
pascal@12756	7162 int FrameClassify( /* index to the max-energy sub-frame */
pascal@12756	7163 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	7164 /* (i/o) the encoder state structure */
pascal@12756	7165 float residual / (i) lpc residual signal */
pascal@12756	7166 );
pascal@12756	7167
pascal@12756	7168
pascal@12756	7169
pascal@12756	7170 Andersen, et al. Experimental [Page 128]
pascal@12756	7171
pascal@12756	7172 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7173
pascal@12756	7174
pascal@12756	7175 #endif
pascal@12756	7176
pascal@12756	7177 A.20. FrameClassify.c
pascal@12756	7178
pascal@12756	7179 /******************************************************************
pascal@12756	7180
pascal@12756	7181 iLBC Speech Coder ANSI-C Source Code
pascal@12756	7182
pascal@12756	7183 FrameClassify.c
pascal@12756	7184
pascal@12756	7185 Copyright (C) The Internet Society (2004).
pascal@12756	7186 All Rights Reserved.
pascal@12756	7187
pascal@12756	7188 ******************************************************************/
pascal@12756	7189
pascal@12756	7190 #include "iLBC_define.h"
pascal@12756	7191
pascal@12756	7192 /---------------------------------------------------------------
pascal@12756	7193 * Classification of subframes to localize start state
pascal@12756	7194 --------------------------------------------------------------/
pascal@12756	7195
pascal@12756	7196 int FrameClassify( /* index to the max-energy sub-frame */
pascal@12756	7197 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	7198 /* (i/o) the encoder state structure */
pascal@12756	7199 float residual / (i) lpc residual signal */
pascal@12756	7200 ) {
pascal@12756	7201 float max_ssqEn, fssqEn[NSUB_MAX], bssqEn[NSUB_MAX], *pp;
pascal@12756	7202 int n, l, max_ssqEn_n;
pascal@12756	7203 const float ssqEn_win[NSUB_MAX-1]={(float)0.8,(float)0.9,
pascal@12756	7204 (float)1.0,(float)0.9,(float)0.8};
pascal@12756	7205 const float sampEn_win[5]={(float)1.0/(float)6.0,
pascal@12756	7206 (float)2.0/(float)6.0, (float)3.0/(float)6.0,
pascal@12756	7207 (float)4.0/(float)6.0, (float)5.0/(float)6.0};
pascal@12756	7208
pascal@12756	7209 /* init the front and back energies to zero */
pascal@12756	7210
pascal@12756	7211 memset(fssqEn, 0, NSUB_MAX*sizeof(float));
pascal@12756	7212 memset(bssqEn, 0, NSUB_MAX*sizeof(float));
pascal@12756	7213
pascal@12756	7214 /* Calculate front of first seqence */
pascal@12756	7215
pascal@12756	7216 n=0;
pascal@12756	7217 pp=residual;
pascal@12756	7218 for (l=0; l<5; l++) {
pascal@12756	7219 fssqEn[n] += sampEn_win[l] * (pp) (*pp);
pascal@12756	7220 pp++;
pascal@12756	7221 }
pascal@12756	7222 for (l=5; l<SUBL; l++) {
pascal@12756	7223
pascal@12756	7224
pascal@12756	7225
pascal@12756	7226 Andersen, et al. Experimental [Page 129]
pascal@12756	7227
pascal@12756	7228 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7229
pascal@12756	7230
pascal@12756	7231 fssqEn[n] += (pp) (*pp);
pascal@12756	7232 pp++;
pascal@12756	7233 }
pascal@12756	7234
pascal@12756	7235 /* Calculate front and back of all middle sequences */
pascal@12756	7236
pascal@12756	7237 for (n=1; n<iLBCenc_inst->nsub-1; n++) {
pascal@12756	7238 pp=residual+n*SUBL;
pascal@12756	7239 for (l=0; l<5; l++) {
pascal@12756	7240 fssqEn[n] += sampEn_win[l] * (pp) (*pp);
pascal@12756	7241 bssqEn[n] += (pp) (*pp);
pascal@12756	7242 pp++;
pascal@12756	7243 }
pascal@12756	7244 for (l=5; l<SUBL-5; l++) {
pascal@12756	7245 fssqEn[n] += (pp) (*pp);
pascal@12756	7246 bssqEn[n] += (pp) (*pp);
pascal@12756	7247 pp++;
pascal@12756	7248 }
pascal@12756	7249 for (l=SUBL-5; l<SUBL; l++) {
pascal@12756	7250 fssqEn[n] += (pp) (*pp);
pascal@12756	7251 bssqEn[n] += sampEn_win[SUBL-l-1] * (pp) (*pp);
pascal@12756	7252 pp++;
pascal@12756	7253 }
pascal@12756	7254 }
pascal@12756	7255
pascal@12756	7256 /* Calculate back of last seqence */
pascal@12756	7257
pascal@12756	7258 n=iLBCenc_inst->nsub-1;
pascal@12756	7259 pp=residual+n*SUBL;
pascal@12756	7260 for (l=0; l<SUBL-5; l++) {
pascal@12756	7261 bssqEn[n] += (pp) (*pp);
pascal@12756	7262 pp++;
pascal@12756	7263 }
pascal@12756	7264 for (l=SUBL-5; l<SUBL; l++) {
pascal@12756	7265 bssqEn[n] += sampEn_win[SUBL-l-1] * (pp) (*pp);
pascal@12756	7266 pp++;
pascal@12756	7267 }
pascal@12756	7268
pascal@12756	7269 /* find the index to the weighted 80 sample with
pascal@12756	7270 most energy */
pascal@12756	7271
pascal@12756	7272 if (iLBCenc_inst->mode==20) l=1;
pascal@12756	7273 else l=0;
pascal@12756	7274
pascal@12756	7275 max_ssqEn=(fssqEn[0]+bssqEn[1])*ssqEn_win[l];
pascal@12756	7276 max_ssqEn_n=1;
pascal@12756	7277 for (n=2; n<iLBCenc_inst->nsub; n++) {
pascal@12756	7278
pascal@12756	7279
pascal@12756	7280
pascal@12756	7281
pascal@12756	7282 Andersen, et al. Experimental [Page 130]
pascal@12756	7283
pascal@12756	7284 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7285
pascal@12756	7286
pascal@12756	7287 l++;
pascal@12756	7288 if ((fssqEn[n-1]+bssqEn[n])*ssqEn_win[l] > max_ssqEn) {
pascal@12756	7289 max_ssqEn=(fssqEn[n-1]+bssqEn[n]) *
pascal@12756	7290 ssqEn_win[l];
pascal@12756	7291 max_ssqEn_n=n;
pascal@12756	7292 }
pascal@12756	7293 }
pascal@12756	7294
pascal@12756	7295 return max_ssqEn_n;
pascal@12756	7296 }
pascal@12756	7297
pascal@12756	7298 A.21. gainquant.h
pascal@12756	7299
pascal@12756	7300 /******************************************************************
pascal@12756	7301
pascal@12756	7302 iLBC Speech Coder ANSI-C Source Code
pascal@12756	7303
pascal@12756	7304 gainquant.h
pascal@12756	7305
pascal@12756	7306 Copyright (C) The Internet Society (2004).
pascal@12756	7307 All Rights Reserved.
pascal@12756	7308
pascal@12756	7309 ******************************************************************/
pascal@12756	7310
pascal@12756	7311 #ifndef __iLBC_GAINQUANT_H
pascal@12756	7312 #define __iLBC_GAINQUANT_H
pascal@12756	7313
pascal@12756	7314 float gainquant(/* (o) quantized gain value */
pascal@12756	7315 float in, /* (i) gain value */
pascal@12756	7316 float maxIn,/* (i) maximum of gain value */
pascal@12756	7317 int cblen, /* (i) number of quantization indices */
pascal@12756	7318 int index / (o) quantization index */
pascal@12756	7319 );
pascal@12756	7320
pascal@12756	7321 float gaindequant( /* (o) quantized gain value */
pascal@12756	7322 int index, /* (i) quantization index */
pascal@12756	7323 float maxIn,/* (i) maximum of unquantized gain */
pascal@12756	7324 int cblen /* (i) number of quantization indices */
pascal@12756	7325 );
pascal@12756	7326
pascal@12756	7327 #endif
pascal@12756	7328
pascal@12756	7329 A.22. gainquant.c
pascal@12756	7330
pascal@12756	7331 /******************************************************************
pascal@12756	7332
pascal@12756	7333 iLBC Speech Coder ANSI-C Source Code
pascal@12756	7334
pascal@12756	7335
pascal@12756	7336
pascal@12756	7337
pascal@12756	7338 Andersen, et al. Experimental [Page 131]
pascal@12756	7339
pascal@12756	7340 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7341
pascal@12756	7342
pascal@12756	7343 gainquant.c
pascal@12756	7344
pascal@12756	7345 Copyright (C) The Internet Society (2004).
pascal@12756	7346 All Rights Reserved.
pascal@12756	7347
pascal@12756	7348 ******************************************************************/
pascal@12756	7349
pascal@12756	7350 #include <string.h>
pascal@12756	7351 #include <math.h>
pascal@12756	7352 #include "constants.h"
pascal@12756	7353 #include "filter.h"
pascal@12756	7354
pascal@12756	7355 /----------------------------------------------------------------
pascal@12756	7356 * quantizer for the gain in the gain-shape coding of residual
pascal@12756	7357 ---------------------------------------------------------------/
pascal@12756	7358
pascal@12756	7359 float gainquant(/* (o) quantized gain value */
pascal@12756	7360 float in, /* (i) gain value */
pascal@12756	7361 float maxIn,/* (i) maximum of gain value */
pascal@12756	7362 int cblen, /* (i) number of quantization indices */
pascal@12756	7363 int index / (o) quantization index */
pascal@12756	7364 ){
pascal@12756	7365 int i, tindex;
pascal@12756	7366 float minmeasure,measure, *cb, scale;
pascal@12756	7367
pascal@12756	7368 /* ensure a lower bound on the scaling factor */
pascal@12756	7369
pascal@12756	7370 scale=maxIn;
pascal@12756	7371
pascal@12756	7372 if (scale<0.1) {
pascal@12756	7373 scale=(float)0.1;
pascal@12756	7374 }
pascal@12756	7375
pascal@12756	7376 /* select the quantization table */
pascal@12756	7377
pascal@12756	7378 if (cblen == 8) {
pascal@12756	7379 cb = gain_sq3Tbl;
pascal@12756	7380 } else if (cblen == 16) {
pascal@12756	7381 cb = gain_sq4Tbl;
pascal@12756	7382 } else {
pascal@12756	7383 cb = gain_sq5Tbl;
pascal@12756	7384 }
pascal@12756	7385
pascal@12756	7386 /* select the best index in the quantization table */
pascal@12756	7387
pascal@12756	7388 minmeasure=10000000.0;
pascal@12756	7389 tindex=0;
pascal@12756	7390 for (i=0; i<cblen; i++) {
pascal@12756	7391
pascal@12756	7392
pascal@12756	7393
pascal@12756	7394 Andersen, et al. Experimental [Page 132]
pascal@12756	7395
pascal@12756	7396 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7397
pascal@12756	7398
pascal@12756	7399 measure=(in-scalecb[i])(in-scale*cb[i]);
pascal@12756	7400
pascal@12756	7401 if (measure<minmeasure) {
pascal@12756	7402 tindex=i;
pascal@12756	7403 minmeasure=measure;
pascal@12756	7404 }
pascal@12756	7405 }
pascal@12756	7406 *index=tindex;
pascal@12756	7407
pascal@12756	7408 /* return the quantized value */
pascal@12756	7409
pascal@12756	7410 return scale*cb[tindex];
pascal@12756	7411 }
pascal@12756	7412
pascal@12756	7413 /----------------------------------------------------------------
pascal@12756	7414 * decoder for quantized gains in the gain-shape coding of
pascal@12756	7415 * residual
pascal@12756	7416 ---------------------------------------------------------------/
pascal@12756	7417
pascal@12756	7418 float gaindequant( /* (o) quantized gain value */
pascal@12756	7419 int index, /* (i) quantization index */
pascal@12756	7420 float maxIn,/* (i) maximum of unquantized gain */
pascal@12756	7421 int cblen /* (i) number of quantization indices */
pascal@12756	7422 ){
pascal@12756	7423 float scale;
pascal@12756	7424
pascal@12756	7425 /* obtain correct scale factor */
pascal@12756	7426
pascal@12756	7427 scale=(float)fabs(maxIn);
pascal@12756	7428
pascal@12756	7429 if (scale<0.1) {
pascal@12756	7430 scale=(float)0.1;
pascal@12756	7431 }
pascal@12756	7432
pascal@12756	7433 /* select the quantization table and return the decoded value */
pascal@12756	7434
pascal@12756	7435 if (cblen==8) {
pascal@12756	7436 return scale*gain_sq3Tbl[index];
pascal@12756	7437 } else if (cblen==16) {
pascal@12756	7438 return scale*gain_sq4Tbl[index];
pascal@12756	7439 }
pascal@12756	7440 else if (cblen==32) {
pascal@12756	7441 return scale*gain_sq5Tbl[index];
pascal@12756	7442 }
pascal@12756	7443
pascal@12756	7444 return 0.0;
pascal@12756	7445 }
pascal@12756	7446
pascal@12756	7447
pascal@12756	7448
pascal@12756	7449
pascal@12756	7450 Andersen, et al. Experimental [Page 133]
pascal@12756	7451
pascal@12756	7452 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7453
pascal@12756	7454
pascal@12756	7455 A.23. getCBvec.h
pascal@12756	7456
pascal@12756	7457 /******************************************************************
pascal@12756	7458
pascal@12756	7459 iLBC Speech Coder ANSI-C Source Code
pascal@12756	7460
pascal@12756	7461 getCBvec.h
pascal@12756	7462
pascal@12756	7463 Copyright (C) The Internet Society (2004).
pascal@12756	7464 All Rights Reserved.
pascal@12756	7465
pascal@12756	7466 ******************************************************************/
pascal@12756	7467
pascal@12756	7468 #ifndef __iLBC_GETCBVEC_H
pascal@12756	7469 #define __iLBC_GETCBVEC_H
pascal@12756	7470
pascal@12756	7471 void getCBvec(
pascal@12756	7472 float cbvec, / (o) Constructed codebook vector */
pascal@12756	7473 float mem, / (i) Codebook buffer */
pascal@12756	7474 int index, /* (i) Codebook index */
pascal@12756	7475 int lMem, /* (i) Length of codebook buffer */
pascal@12756	7476 int cbveclen/* (i) Codebook vector length */
pascal@12756	7477 );
pascal@12756	7478
pascal@12756	7479 #endif
pascal@12756	7480
pascal@12756	7481 A.24. getCBvec.c
pascal@12756	7482
pascal@12756	7483 /******************************************************************
pascal@12756	7484
pascal@12756	7485 iLBC Speech Coder ANSI-C Source Code
pascal@12756	7486
pascal@12756	7487 getCBvec.c
pascal@12756	7488
pascal@12756	7489 Copyright (C) The Internet Society (2004).
pascal@12756	7490 All Rights Reserved.
pascal@12756	7491
pascal@12756	7492 ******************************************************************/
pascal@12756	7493
pascal@12756	7494 #include "iLBC_define.h"
pascal@12756	7495 #include "constants.h"
pascal@12756	7496 #include <string.h>
pascal@12756	7497
pascal@12756	7498 /----------------------------------------------------------------
pascal@12756	7499 * Construct codebook vector for given index.
pascal@12756	7500 ---------------------------------------------------------------/
pascal@12756	7501
pascal@12756	7502 void getCBvec(
pascal@12756	7503
pascal@12756	7504
pascal@12756	7505
pascal@12756	7506 Andersen, et al. Experimental [Page 134]
pascal@12756	7507
pascal@12756	7508 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7509
pascal@12756	7510
pascal@12756	7511 float cbvec, / (o) Constructed codebook vector */
pascal@12756	7512 float mem, / (i) Codebook buffer */
pascal@12756	7513 int index, /* (i) Codebook index */
pascal@12756	7514 int lMem, /* (i) Length of codebook buffer */
pascal@12756	7515 int cbveclen/* (i) Codebook vector length */
pascal@12756	7516 ){
pascal@12756	7517 int j, k, n, memInd, sFilt;
pascal@12756	7518 float tmpbuf[CB_MEML];
pascal@12756	7519 int base_size;
pascal@12756	7520 int ilow, ihigh;
pascal@12756	7521 float alfa, alfa1;
pascal@12756	7522
pascal@12756	7523 /* Determine size of codebook sections */
pascal@12756	7524
pascal@12756	7525 base_size=lMem-cbveclen+1;
pascal@12756	7526
pascal@12756	7527 if (cbveclen==SUBL) {
pascal@12756	7528 base_size+=cbveclen/2;
pascal@12756	7529 }
pascal@12756	7530
pascal@12756	7531 /* No filter -> First codebook section */
pascal@12756	7532
pascal@12756	7533 if (index<lMem-cbveclen+1) {
pascal@12756	7534
pascal@12756	7535 /* first non-interpolated vectors */
pascal@12756	7536
pascal@12756	7537 k=index+cbveclen;
pascal@12756	7538 /* get vector */
pascal@12756	7539 memcpy(cbvec, mem+lMem-k, cbveclen*sizeof(float));
pascal@12756	7540
pascal@12756	7541 } else if (index < base_size) {
pascal@12756	7542
pascal@12756	7543 k=2*(index-(lMem-cbveclen+1))+cbveclen;
pascal@12756	7544
pascal@12756	7545 ihigh=k/2;
pascal@12756	7546 ilow=ihigh-5;
pascal@12756	7547
pascal@12756	7548 /* Copy first noninterpolated part */
pascal@12756	7549
pascal@12756	7550 memcpy(cbvec, mem+lMem-k/2, ilow*sizeof(float));
pascal@12756	7551
pascal@12756	7552 /* interpolation */
pascal@12756	7553
pascal@12756	7554 alfa1=(float)0.2;
pascal@12756	7555 alfa=0.0;
pascal@12756	7556 for (j=ilow; j<ihigh; j++) {
pascal@12756	7557 cbvec[j]=((float)1.0-alfa)*mem[lMem-k/2+j]+
pascal@12756	7558 alfa*mem[lMem-k+j];
pascal@12756	7559
pascal@12756	7560
pascal@12756	7561
pascal@12756	7562 Andersen, et al. Experimental [Page 135]
pascal@12756	7563
pascal@12756	7564 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7565
pascal@12756	7566
pascal@12756	7567 alfa+=alfa1;
pascal@12756	7568 }
pascal@12756	7569
pascal@12756	7570 /* Copy second noninterpolated part */
pascal@12756	7571
pascal@12756	7572 memcpy(cbvec+ihigh, mem+lMem-k+ihigh,
pascal@12756	7573 (cbveclen-ihigh)*sizeof(float));
pascal@12756	7574
pascal@12756	7575 }
pascal@12756	7576
pascal@12756	7577 /* Higher codebook section based on filtering */
pascal@12756	7578
pascal@12756	7579 else {
pascal@12756	7580
pascal@12756	7581 /* first non-interpolated vectors */
pascal@12756	7582
pascal@12756	7583 if (index-base_size<lMem-cbveclen+1) {
pascal@12756	7584 float tempbuff2[CB_MEML+CB_FILTERLEN+1];
pascal@12756	7585 float *pos;
pascal@12756	7586 float pp, pp1;
pascal@12756	7587
pascal@12756	7588 memset(tempbuff2, 0,
pascal@12756	7589 CB_HALFFILTERLEN*sizeof(float));
pascal@12756	7590 memcpy(&tempbuff2[CB_HALFFILTERLEN], mem,
pascal@12756	7591 lMem*sizeof(float));
pascal@12756	7592 memset(&tempbuff2[lMem+CB_HALFFILTERLEN], 0,
pascal@12756	7593 (CB_HALFFILTERLEN+1)*sizeof(float));
pascal@12756	7594
pascal@12756	7595 k=index-base_size+cbveclen;
pascal@12756	7596 sFilt=lMem-k;
pascal@12756	7597 memInd=sFilt+1-CB_HALFFILTERLEN;
pascal@12756	7598
pascal@12756	7599 /* do filtering */
pascal@12756	7600 pos=cbvec;
pascal@12756	7601 memset(pos, 0, cbveclen*sizeof(float));
pascal@12756	7602 for (n=0; n<cbveclen; n++) {
pascal@12756	7603 pp=&tempbuff2[memInd+n+CB_HALFFILTERLEN];
pascal@12756	7604 pp1=&cbfiltersTbl[CB_FILTERLEN-1];
pascal@12756	7605 for (j=0; j<CB_FILTERLEN; j++) {
pascal@12756	7606 (pos)+=(pp++)(pp1--);
pascal@12756	7607 }
pascal@12756	7608 pos++;
pascal@12756	7609 }
pascal@12756	7610 }
pascal@12756	7611
pascal@12756	7612 /* interpolated vectors */
pascal@12756	7613
pascal@12756	7614 else {
pascal@12756	7615
pascal@12756	7616
pascal@12756	7617
pascal@12756	7618 Andersen, et al. Experimental [Page 136]
pascal@12756	7619
pascal@12756	7620 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7621
pascal@12756	7622
pascal@12756	7623 float tempbuff2[CB_MEML+CB_FILTERLEN+1];
pascal@12756	7624
pascal@12756	7625 float *pos;
pascal@12756	7626 float pp, pp1;
pascal@12756	7627 int i;
pascal@12756	7628
pascal@12756	7629 memset(tempbuff2, 0,
pascal@12756	7630 CB_HALFFILTERLEN*sizeof(float));
pascal@12756	7631 memcpy(&tempbuff2[CB_HALFFILTERLEN], mem,
pascal@12756	7632 lMem*sizeof(float));
pascal@12756	7633 memset(&tempbuff2[lMem+CB_HALFFILTERLEN], 0,
pascal@12756	7634 (CB_HALFFILTERLEN+1)*sizeof(float));
pascal@12756	7635
pascal@12756	7636 k=2*(index-base_size-
pascal@12756	7637 (lMem-cbveclen+1))+cbveclen;
pascal@12756	7638 sFilt=lMem-k;
pascal@12756	7639 memInd=sFilt+1-CB_HALFFILTERLEN;
pascal@12756	7640
pascal@12756	7641 /* do filtering */
pascal@12756	7642 pos=&tmpbuf[sFilt];
pascal@12756	7643 memset(pos, 0, k*sizeof(float));
pascal@12756	7644 for (i=0; i<k; i++) {
pascal@12756	7645 pp=&tempbuff2[memInd+i+CB_HALFFILTERLEN];
pascal@12756	7646 pp1=&cbfiltersTbl[CB_FILTERLEN-1];
pascal@12756	7647 for (j=0; j<CB_FILTERLEN; j++) {
pascal@12756	7648 (pos)+=(pp++)(pp1--);
pascal@12756	7649 }
pascal@12756	7650 pos++;
pascal@12756	7651 }
pascal@12756	7652
pascal@12756	7653 ihigh=k/2;
pascal@12756	7654 ilow=ihigh-5;
pascal@12756	7655
pascal@12756	7656 /* Copy first noninterpolated part */
pascal@12756	7657
pascal@12756	7658 memcpy(cbvec, tmpbuf+lMem-k/2,
pascal@12756	7659 ilow*sizeof(float));
pascal@12756	7660
pascal@12756	7661 /* interpolation */
pascal@12756	7662
pascal@12756	7663 alfa1=(float)0.2;
pascal@12756	7664 alfa=0.0;
pascal@12756	7665 for (j=ilow; j<ihigh; j++) {
pascal@12756	7666 cbvec[j]=((float)1.0-alfa)*
pascal@12756	7667 tmpbuf[lMem-k/2+j]+alfa*tmpbuf[lMem-k+j];
pascal@12756	7668 alfa+=alfa1;
pascal@12756	7669 }
pascal@12756	7670
pascal@12756	7671
pascal@12756	7672
pascal@12756	7673
pascal@12756	7674 Andersen, et al. Experimental [Page 137]
pascal@12756	7675
pascal@12756	7676 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7677
pascal@12756	7678
pascal@12756	7679 /* Copy second noninterpolated part */
pascal@12756	7680
pascal@12756	7681 memcpy(cbvec+ihigh, tmpbuf+lMem-k+ihigh,
pascal@12756	7682 (cbveclen-ihigh)*sizeof(float));
pascal@12756	7683 }
pascal@12756	7684 }
pascal@12756	7685 }
pascal@12756	7686
pascal@12756	7687 A.25. helpfun.h
pascal@12756	7688
pascal@12756	7689 /******************************************************************
pascal@12756	7690
pascal@12756	7691 iLBC Speech Coder ANSI-C Source Code
pascal@12756	7692
pascal@12756	7693 helpfun.h
pascal@12756	7694
pascal@12756	7695 Copyright (C) The Internet Society (2004).
pascal@12756	7696 All Rights Reserved.
pascal@12756	7697
pascal@12756	7698 ******************************************************************/
pascal@12756	7699
pascal@12756	7700 #ifndef __iLBC_HELPFUN_H
pascal@12756	7701 #define __iLBC_HELPFUN_H
pascal@12756	7702
pascal@12756	7703 void autocorr(
pascal@12756	7704 float r, / (o) autocorrelation vector */
pascal@12756	7705 const float x, / (i) data vector */
pascal@12756	7706 int N, /* (i) length of data vector */
pascal@12756	7707 int order /* largest lag for calculated
pascal@12756	7708 autocorrelations */
pascal@12756	7709 );
pascal@12756	7710
pascal@12756	7711 void window(
pascal@12756	7712 float z, / (o) the windowed data */
pascal@12756	7713 const float x, / (i) the original data vector */
pascal@12756	7714 const float y, / (i) the window */
pascal@12756	7715 int N /* (i) length of all vectors */
pascal@12756	7716 );
pascal@12756	7717
pascal@12756	7718 void levdurb(
pascal@12756	7719 float a, / (o) lpc coefficient vector starting
pascal@12756	7720 with 1.0 */
pascal@12756	7721 float k, / (o) reflection coefficients */
pascal@12756	7722 float r, / (i) autocorrelation vector */
pascal@12756	7723 int order /* (i) order of lpc filter */
pascal@12756	7724 );
pascal@12756	7725
pascal@12756	7726 void interpolate(
pascal@12756	7727
pascal@12756	7728
pascal@12756	7729
pascal@12756	7730 Andersen, et al. Experimental [Page 138]
pascal@12756	7731
pascal@12756	7732 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7733
pascal@12756	7734
pascal@12756	7735 float out, / (o) the interpolated vector */
pascal@12756	7736 float in1, / (i) the first vector for the
pascal@12756	7737 interpolation */
pascal@12756	7738 float in2, / (i) the second vector for the
pascal@12756	7739 interpolation */
pascal@12756	7740 float coef, /* (i) interpolation weights */
pascal@12756	7741 int length /* (i) length of all vectors */
pascal@12756	7742 );
pascal@12756	7743
pascal@12756	7744 void bwexpand(
pascal@12756	7745 float out, / (o) the bandwidth expanded lpc
pascal@12756	7746 coefficients */
pascal@12756	7747 float in, / (i) the lpc coefficients before bandwidth
pascal@12756	7748 expansion */
pascal@12756	7749 float coef, /* (i) the bandwidth expansion factor */
pascal@12756	7750 int length /* (i) the length of lpc coefficient vectors */
pascal@12756	7751 );
pascal@12756	7752
pascal@12756	7753 void vq(
pascal@12756	7754 float Xq, / (o) the quantized vector */
pascal@12756	7755 int index, / (o) the quantization index */
pascal@12756	7756 const float CB,/ (i) the vector quantization codebook */
pascal@12756	7757 float X, / (i) the vector to quantize */
pascal@12756	7758 int n_cb, /* (i) the number of vectors in the codebook */
pascal@12756	7759 int dim /* (i) the dimension of all vectors */
pascal@12756	7760 );
pascal@12756	7761
pascal@12756	7762 void SplitVQ(
pascal@12756	7763 float qX, / (o) the quantized vector */
pascal@12756	7764 int index, / (o) a vector of indexes for all vector
pascal@12756	7765 codebooks in the split */
pascal@12756	7766 float X, / (i) the vector to quantize */
pascal@12756	7767 const float CB,/ (i) the quantizer codebook */
pascal@12756	7768 int nsplit, /* the number of vector splits */
pascal@12756	7769 const int dim, / the dimension of X and qX */
pascal@12756	7770 const int cbsize / the number of vectors in the codebook */
pascal@12756	7771 );
pascal@12756	7772
pascal@12756	7773
pascal@12756	7774 void sort_sq(
pascal@12756	7775 float xq, / (o) the quantized value */
pascal@12756	7776 int index, / (o) the quantization index */
pascal@12756	7777 float x, /* (i) the value to quantize */
pascal@12756	7778 const float cb,/ (i) the quantization codebook */
pascal@12756	7779 int cb_size /* (i) the size of the quantization codebook */
pascal@12756	7780 );
pascal@12756	7781
pascal@12756	7782 int LSF_check( /* (o) 1 for stable lsf vectors and 0 for
pascal@12756	7783
pascal@12756	7784
pascal@12756	7785
pascal@12756	7786 Andersen, et al. Experimental [Page 139]
pascal@12756	7787
pascal@12756	7788 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7789
pascal@12756	7790
pascal@12756	7791 nonstable ones */
pascal@12756	7792 float lsf, / (i) a table of lsf vectors */
pascal@12756	7793 int dim, /* (i) the dimension of each lsf vector */
pascal@12756	7794 int NoAn /* (i) the number of lsf vectors in the
pascal@12756	7795 table */
pascal@12756	7796 );
pascal@12756	7797
pascal@12756	7798 #endif
pascal@12756	7799
pascal@12756	7800 A.26. helpfun.c
pascal@12756	7801
pascal@12756	7802 /******************************************************************
pascal@12756	7803
pascal@12756	7804 iLBC Speech Coder ANSI-C Source Code
pascal@12756	7805
pascal@12756	7806 helpfun.c
pascal@12756	7807
pascal@12756	7808 Copyright (C) The Internet Society (2004).
pascal@12756	7809 All Rights Reserved.
pascal@12756	7810
pascal@12756	7811 ******************************************************************/
pascal@12756	7812
pascal@12756	7813 #include <math.h>
pascal@12756	7814
pascal@12756	7815 #include "iLBC_define.h"
pascal@12756	7816 #include "constants.h"
pascal@12756	7817
pascal@12756	7818 /----------------------------------------------------------------
pascal@12756	7819 * calculation of auto correlation
pascal@12756	7820 ---------------------------------------------------------------/
pascal@12756	7821
pascal@12756	7822 void autocorr(
pascal@12756	7823 float r, / (o) autocorrelation vector */
pascal@12756	7824 const float x, / (i) data vector */
pascal@12756	7825 int N, /* (i) length of data vector */
pascal@12756	7826 int order /* largest lag for calculated
pascal@12756	7827 autocorrelations */
pascal@12756	7828 ){
pascal@12756	7829 int lag, n;
pascal@12756	7830 float sum;
pascal@12756	7831
pascal@12756	7832 for (lag = 0; lag <= order; lag++) {
pascal@12756	7833 sum = 0;
pascal@12756	7834 for (n = 0; n < N - lag; n++) {
pascal@12756	7835 sum += x[n] * x[n+lag];
pascal@12756	7836 }
pascal@12756	7837 r[lag] = sum;
pascal@12756	7838 }
pascal@12756	7839
pascal@12756	7840
pascal@12756	7841
pascal@12756	7842 Andersen, et al. Experimental [Page 140]
pascal@12756	7843
pascal@12756	7844 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7845
pascal@12756	7846
pascal@12756	7847 }
pascal@12756	7848
pascal@12756	7849 /----------------------------------------------------------------
pascal@12756	7850 * window multiplication
pascal@12756	7851 ---------------------------------------------------------------/
pascal@12756	7852
pascal@12756	7853 void window(
pascal@12756	7854 float z, / (o) the windowed data */
pascal@12756	7855 const float x, / (i) the original data vector */
pascal@12756	7856 const float y, / (i) the window */
pascal@12756	7857 int N /* (i) length of all vectors */
pascal@12756	7858 ){
pascal@12756	7859 int i;
pascal@12756	7860
pascal@12756	7861 for (i = 0; i < N; i++) {
pascal@12756	7862 z[i] = x[i] * y[i];
pascal@12756	7863 }
pascal@12756	7864 }
pascal@12756	7865
pascal@12756	7866 /----------------------------------------------------------------
pascal@12756	7867 * levinson-durbin solution for lpc coefficients
pascal@12756	7868 ---------------------------------------------------------------/
pascal@12756	7869
pascal@12756	7870 void levdurb(
pascal@12756	7871 float a, / (o) lpc coefficient vector starting
pascal@12756	7872 with 1.0 */
pascal@12756	7873 float k, / (o) reflection coefficients */
pascal@12756	7874 float r, / (i) autocorrelation vector */
pascal@12756	7875 int order /* (i) order of lpc filter */
pascal@12756	7876 ){
pascal@12756	7877 float sum, alpha;
pascal@12756	7878 int m, m_h, i;
pascal@12756	7879
pascal@12756	7880 a[0] = 1.0;
pascal@12756	7881
pascal@12756	7882 if (r[0] < EPS) { /* if r[0] <= 0, set LPC coeff. to zero */
pascal@12756	7883 for (i = 0; i < order; i++) {
pascal@12756	7884 k[i] = 0;
pascal@12756	7885 a[i+1] = 0;
pascal@12756	7886 }
pascal@12756	7887 } else {
pascal@12756	7888 a[1] = k[0] = -r[1]/r[0];
pascal@12756	7889 alpha = r[0] + r[1] * k[0];
pascal@12756	7890 for (m = 1; m < order; m++){
pascal@12756	7891 sum = r[m + 1];
pascal@12756	7892 for (i = 0; i < m; i++){
pascal@12756	7893 sum += a[i+1] * r[m - i];
pascal@12756	7894 }
pascal@12756	7895
pascal@12756	7896
pascal@12756	7897
pascal@12756	7898 Andersen, et al. Experimental [Page 141]
pascal@12756	7899
pascal@12756	7900 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7901
pascal@12756	7902
pascal@12756	7903 k[m] = -sum / alpha;
pascal@12756	7904 alpha += k[m] * sum;
pascal@12756	7905 m_h = (m + 1) >> 1;
pascal@12756	7906 for (i = 0; i < m_h; i++){
pascal@12756	7907 sum = a[i+1] + k[m] * a[m - i];
pascal@12756	7908 a[m - i] += k[m] * a[i+1];
pascal@12756	7909 a[i+1] = sum;
pascal@12756	7910 }
pascal@12756	7911 a[m+1] = k[m];
pascal@12756	7912 }
pascal@12756	7913 }
pascal@12756	7914 }
pascal@12756	7915
pascal@12756	7916 /----------------------------------------------------------------
pascal@12756	7917 * interpolation between vectors
pascal@12756	7918 ---------------------------------------------------------------/
pascal@12756	7919
pascal@12756	7920 void interpolate(
pascal@12756	7921 float out, / (o) the interpolated vector */
pascal@12756	7922 float in1, / (i) the first vector for the
pascal@12756	7923 interpolation */
pascal@12756	7924 float in2, / (i) the second vector for the
pascal@12756	7925 interpolation */
pascal@12756	7926 float coef, /* (i) interpolation weights */
pascal@12756	7927 int length /* (i) length of all vectors */
pascal@12756	7928 ){
pascal@12756	7929 int i;
pascal@12756	7930 float invcoef;
pascal@12756	7931
pascal@12756	7932 invcoef = (float)1.0 - coef;
pascal@12756	7933 for (i = 0; i < length; i++) {
pascal@12756	7934 out[i] = coef * in1[i] + invcoef * in2[i];
pascal@12756	7935 }
pascal@12756	7936 }
pascal@12756	7937
pascal@12756	7938 /----------------------------------------------------------------
pascal@12756	7939 * lpc bandwidth expansion
pascal@12756	7940 ---------------------------------------------------------------/
pascal@12756	7941
pascal@12756	7942 void bwexpand(
pascal@12756	7943 float out, / (o) the bandwidth expanded lpc
pascal@12756	7944 coefficients */
pascal@12756	7945 float in, / (i) the lpc coefficients before bandwidth
pascal@12756	7946 expansion */
pascal@12756	7947 float coef, /* (i) the bandwidth expansion factor */
pascal@12756	7948 int length /* (i) the length of lpc coefficient vectors */
pascal@12756	7949 ){
pascal@12756	7950 int i;
pascal@12756	7951
pascal@12756	7952
pascal@12756	7953
pascal@12756	7954 Andersen, et al. Experimental [Page 142]
pascal@12756	7955
pascal@12756	7956 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	7957
pascal@12756	7958
pascal@12756	7959 float chirp;
pascal@12756	7960
pascal@12756	7961 chirp = coef;
pascal@12756	7962
pascal@12756	7963 out[0] = in[0];
pascal@12756	7964 for (i = 1; i < length; i++) {
pascal@12756	7965 out[i] = chirp * in[i];
pascal@12756	7966 chirp *= coef;
pascal@12756	7967 }
pascal@12756	7968 }
pascal@12756	7969
pascal@12756	7970 /----------------------------------------------------------------
pascal@12756	7971 * vector quantization
pascal@12756	7972 ---------------------------------------------------------------/
pascal@12756	7973
pascal@12756	7974 void vq(
pascal@12756	7975 float Xq, / (o) the quantized vector */
pascal@12756	7976 int index, / (o) the quantization index */
pascal@12756	7977 const float CB,/ (i) the vector quantization codebook */
pascal@12756	7978 float X, / (i) the vector to quantize */
pascal@12756	7979 int n_cb, /* (i) the number of vectors in the codebook */
pascal@12756	7980 int dim /* (i) the dimension of all vectors */
pascal@12756	7981 ){
pascal@12756	7982 int i, j;
pascal@12756	7983 int pos, minindex;
pascal@12756	7984 float dist, tmp, mindist;
pascal@12756	7985
pascal@12756	7986 pos = 0;
pascal@12756	7987 mindist = FLOAT_MAX;
pascal@12756	7988 minindex = 0;
pascal@12756	7989 for (j = 0; j < n_cb; j++) {
pascal@12756	7990 dist = X[0] - CB[pos];
pascal@12756	7991 dist *= dist;
pascal@12756	7992 for (i = 1; i < dim; i++) {
pascal@12756	7993 tmp = X[i] - CB[pos + i];
pascal@12756	7994 dist += tmp*tmp;
pascal@12756	7995 }
pascal@12756	7996
pascal@12756	7997 if (dist < mindist) {
pascal@12756	7998 mindist = dist;
pascal@12756	7999 minindex = j;
pascal@12756	8000 }
pascal@12756	8001 pos += dim;
pascal@12756	8002 }
pascal@12756	8003 for (i = 0; i < dim; i++) {
pascal@12756	8004 Xq[i] = CB[minindex*dim + i];
pascal@12756	8005 }
pascal@12756	8006 *index = minindex;
pascal@12756	8007
pascal@12756	8008
pascal@12756	8009
pascal@12756	8010 Andersen, et al. Experimental [Page 143]
pascal@12756	8011
pascal@12756	8012 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8013
pascal@12756	8014
pascal@12756	8015 }
pascal@12756	8016
pascal@12756	8017 /----------------------------------------------------------------
pascal@12756	8018 * split vector quantization
pascal@12756	8019 ---------------------------------------------------------------/
pascal@12756	8020
pascal@12756	8021 void SplitVQ(
pascal@12756	8022 float qX, / (o) the quantized vector */
pascal@12756	8023 int index, / (o) a vector of indexes for all vector
pascal@12756	8024 codebooks in the split */
pascal@12756	8025 float X, / (i) the vector to quantize */
pascal@12756	8026 const float CB,/ (i) the quantizer codebook */
pascal@12756	8027 int nsplit, /* the number of vector splits */
pascal@12756	8028 const int dim, / the dimension of X and qX */
pascal@12756	8029 const int cbsize / the number of vectors in the codebook */
pascal@12756	8030 ){
pascal@12756	8031 int cb_pos, X_pos, i;
pascal@12756	8032
pascal@12756	8033 cb_pos = 0;
pascal@12756	8034 X_pos= 0;
pascal@12756	8035 for (i = 0; i < nsplit; i++) {
pascal@12756	8036 vq(qX + X_pos, index + i, CB + cb_pos, X + X_pos,
pascal@12756	8037 cbsize[i], dim[i]);
pascal@12756	8038 X_pos += dim[i];
pascal@12756	8039 cb_pos += dim[i] * cbsize[i];
pascal@12756	8040 }
pascal@12756	8041 }
pascal@12756	8042
pascal@12756	8043 /----------------------------------------------------------------
pascal@12756	8044 * scalar quantization
pascal@12756	8045 ---------------------------------------------------------------/
pascal@12756	8046
pascal@12756	8047 void sort_sq(
pascal@12756	8048 float xq, / (o) the quantized value */
pascal@12756	8049 int index, / (o) the quantization index */
pascal@12756	8050 float x, /* (i) the value to quantize */
pascal@12756	8051 const float cb,/ (i) the quantization codebook */
pascal@12756	8052 int cb_size /* (i) the size of the quantization codebook */
pascal@12756	8053 ){
pascal@12756	8054 int i;
pascal@12756	8055
pascal@12756	8056 if (x <= cb[0]) {
pascal@12756	8057 *index = 0;
pascal@12756	8058 *xq = cb[0];
pascal@12756	8059 } else {
pascal@12756	8060 i = 0;
pascal@12756	8061 while ((x > cb[i]) && i < cb_size - 1) {
pascal@12756	8062 i++;
pascal@12756	8063
pascal@12756	8064
pascal@12756	8065
pascal@12756	8066 Andersen, et al. Experimental [Page 144]
pascal@12756	8067
pascal@12756	8068 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8069
pascal@12756	8070
pascal@12756	8071 }
pascal@12756	8072
pascal@12756	8073 if (x > ((cb[i] + cb[i - 1])/2)) {
pascal@12756	8074 *index = i;
pascal@12756	8075 *xq = cb[i];
pascal@12756	8076 } else {
pascal@12756	8077 *index = i - 1;
pascal@12756	8078 *xq = cb[i - 1];
pascal@12756	8079 }
pascal@12756	8080 }
pascal@12756	8081 }
pascal@12756	8082
pascal@12756	8083 /----------------------------------------------------------------
pascal@12756	8084 * check for stability of lsf coefficients
pascal@12756	8085 ---------------------------------------------------------------/
pascal@12756	8086
pascal@12756	8087 int LSF_check( /* (o) 1 for stable lsf vectors and 0 for
pascal@12756	8088 nonstable ones */
pascal@12756	8089 float lsf, / (i) a table of lsf vectors */
pascal@12756	8090 int dim, /* (i) the dimension of each lsf vector */
pascal@12756	8091 int NoAn /* (i) the number of lsf vectors in the
pascal@12756	8092 table */
pascal@12756	8093 ){
pascal@12756	8094 int k,n,m, Nit=2, change=0,pos;
pascal@12756	8095 float tmp;
pascal@12756	8096 static float eps=(float)0.039; /* 50 Hz */
pascal@12756	8097 static float eps2=(float)0.0195;
pascal@12756	8098 static float maxlsf=(float)3.14; /* 4000 Hz */
pascal@12756	8099 static float minlsf=(float)0.01; /* 0 Hz */
pascal@12756	8100
pascal@12756	8101 /* LSF separation check*/
pascal@12756	8102
pascal@12756	8103 for (n=0; n<Nit; n++) { /* Run through a couple of times */
pascal@12756	8104 for (m=0; m<NoAn; m++) { /* Number of analyses per frame */
pascal@12756	8105 for (k=0; k<(dim-1); k++) {
pascal@12756	8106 pos=m*dim+k;
pascal@12756	8107
pascal@12756	8108 if ((lsf[pos+1]-lsf[pos])<eps) {
pascal@12756	8109
pascal@12756	8110 if (lsf[pos+1]<lsf[pos]) {
pascal@12756	8111 tmp=lsf[pos+1];
pascal@12756	8112 lsf[pos+1]= lsf[pos]+eps2;
pascal@12756	8113 lsf[pos]= lsf[pos+1]-eps2;
pascal@12756	8114 } else {
pascal@12756	8115 lsf[pos]-=eps2;
pascal@12756	8116 lsf[pos+1]+=eps2;
pascal@12756	8117 }
pascal@12756	8118 change=1;
pascal@12756	8119
pascal@12756	8120
pascal@12756	8121
pascal@12756	8122 Andersen, et al. Experimental [Page 145]
pascal@12756	8123
pascal@12756	8124 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8125
pascal@12756	8126
pascal@12756	8127 }
pascal@12756	8128
pascal@12756	8129 if (lsf[pos]<minlsf) {
pascal@12756	8130 lsf[pos]=minlsf;
pascal@12756	8131 change=1;
pascal@12756	8132 }
pascal@12756	8133
pascal@12756	8134 if (lsf[pos]>maxlsf) {
pascal@12756	8135 lsf[pos]=maxlsf;
pascal@12756	8136 change=1;
pascal@12756	8137 }
pascal@12756	8138 }
pascal@12756	8139 }
pascal@12756	8140 }
pascal@12756	8141
pascal@12756	8142 return change;
pascal@12756	8143 }
pascal@12756	8144
pascal@12756	8145 A.27. hpInput.h
pascal@12756	8146
pascal@12756	8147 /******************************************************************
pascal@12756	8148
pascal@12756	8149 iLBC Speech Coder ANSI-C Source Code
pascal@12756	8150
pascal@12756	8151 hpInput.h
pascal@12756	8152
pascal@12756	8153 Copyright (C) The Internet Society (2004).
pascal@12756	8154 All Rights Reserved.
pascal@12756	8155
pascal@12756	8156 ******************************************************************/
pascal@12756	8157
pascal@12756	8158 #ifndef __iLBC_HPINPUT_H
pascal@12756	8159 #define __iLBC_HPINPUT_H
pascal@12756	8160
pascal@12756	8161 void hpInput(
pascal@12756	8162 float In, / (i) vector to filter */
pascal@12756	8163 int len, /* (i) length of vector to filter */
pascal@12756	8164 float Out, / (o) the resulting filtered vector */
pascal@12756	8165 float mem / (i/o) the filter state */
pascal@12756	8166 );
pascal@12756	8167
pascal@12756	8168 #endif
pascal@12756	8169
pascal@12756	8170 A.28. hpInput.c
pascal@12756	8171
pascal@12756	8172 /******************************************************************
pascal@12756	8173
pascal@12756	8174 iLBC Speech Coder ANSI-C Source Code
pascal@12756	8175
pascal@12756	8176
pascal@12756	8177
pascal@12756	8178 Andersen, et al. Experimental [Page 146]
pascal@12756	8179
pascal@12756	8180 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8181
pascal@12756	8182
pascal@12756	8183 hpInput.c
pascal@12756	8184
pascal@12756	8185 Copyright (C) The Internet Society (2004).
pascal@12756	8186 All Rights Reserved.
pascal@12756	8187
pascal@12756	8188 ******************************************************************/
pascal@12756	8189
pascal@12756	8190 #include "constants.h"
pascal@12756	8191
pascal@12756	8192 /----------------------------------------------------------------
pascal@12756	8193 * Input high-pass filter
pascal@12756	8194 ---------------------------------------------------------------/
pascal@12756	8195
pascal@12756	8196 void hpInput(
pascal@12756	8197 float In, / (i) vector to filter */
pascal@12756	8198 int len, /* (i) length of vector to filter */
pascal@12756	8199 float Out, / (o) the resulting filtered vector */
pascal@12756	8200 float mem / (i/o) the filter state */
pascal@12756	8201 ){
pascal@12756	8202 int i;
pascal@12756	8203 float pi, po;
pascal@12756	8204
pascal@12756	8205 /* all-zero section*/
pascal@12756	8206
pascal@12756	8207 pi = &In[0];
pascal@12756	8208 po = &Out[0];
pascal@12756	8209 for (i=0; i<len; i++) {
pascal@12756	8210 po = hpi_zero_coefsTbl[0] (*pi);
pascal@12756	8211 po += hpi_zero_coefsTbl[1] mem[0];
pascal@12756	8212 po += hpi_zero_coefsTbl[2] mem[1];
pascal@12756	8213
pascal@12756	8214 mem[1] = mem[0];
pascal@12756	8215 mem[0] = *pi;
pascal@12756	8216 po++;
pascal@12756	8217 pi++;
pascal@12756	8218
pascal@12756	8219 }
pascal@12756	8220
pascal@12756	8221 /* all-pole section*/
pascal@12756	8222
pascal@12756	8223 po = &Out[0];
pascal@12756	8224 for (i=0; i<len; i++) {
pascal@12756	8225 po -= hpi_pole_coefsTbl[1] mem[2];
pascal@12756	8226 po -= hpi_pole_coefsTbl[2] mem[3];
pascal@12756	8227
pascal@12756	8228 mem[3] = mem[2];
pascal@12756	8229 mem[2] = *po;
pascal@12756	8230 po++;
pascal@12756	8231
pascal@12756	8232
pascal@12756	8233
pascal@12756	8234 Andersen, et al. Experimental [Page 147]
pascal@12756	8235
pascal@12756	8236 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8237
pascal@12756	8238
pascal@12756	8239 }
pascal@12756	8240 }
pascal@12756	8241
pascal@12756	8242 A.29. hpOutput.h
pascal@12756	8243
pascal@12756	8244 /******************************************************************
pascal@12756	8245
pascal@12756	8246 iLBC Speech Coder ANSI-C Source Code
pascal@12756	8247
pascal@12756	8248 hpOutput.h
pascal@12756	8249
pascal@12756	8250 Copyright (C) The Internet Society (2004).
pascal@12756	8251 All Rights Reserved.
pascal@12756	8252
pascal@12756	8253 ******************************************************************/
pascal@12756	8254
pascal@12756	8255 #ifndef __iLBC_HPOUTPUT_H
pascal@12756	8256 #define __iLBC_HPOUTPUT_H
pascal@12756	8257
pascal@12756	8258 void hpOutput(
pascal@12756	8259 float In, / (i) vector to filter */
pascal@12756	8260 int len,/* (i) length of vector to filter */
pascal@12756	8261 float Out, / (o) the resulting filtered vector */
pascal@12756	8262 float mem / (i/o) the filter state */
pascal@12756	8263 );
pascal@12756	8264
pascal@12756	8265 #endif
pascal@12756	8266
pascal@12756	8267 A.30. hpOutput.c
pascal@12756	8268
pascal@12756	8269 /******************************************************************
pascal@12756	8270
pascal@12756	8271 iLBC Speech Coder ANSI-C Source Code
pascal@12756	8272
pascal@12756	8273 hpOutput.c
pascal@12756	8274
pascal@12756	8275 Copyright (C) The Internet Society (2004).
pascal@12756	8276 All Rights Reserved.
pascal@12756	8277
pascal@12756	8278 ******************************************************************/
pascal@12756	8279
pascal@12756	8280 #include "constants.h"
pascal@12756	8281
pascal@12756	8282 /----------------------------------------------------------------
pascal@12756	8283 * Output high-pass filter
pascal@12756	8284 ---------------------------------------------------------------/
pascal@12756	8285
pascal@12756	8286 void hpOutput(
pascal@12756	8287
pascal@12756	8288
pascal@12756	8289
pascal@12756	8290 Andersen, et al. Experimental [Page 148]
pascal@12756	8291
pascal@12756	8292 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8293
pascal@12756	8294
pascal@12756	8295 float In, / (i) vector to filter */
pascal@12756	8296 int len,/* (i) length of vector to filter */
pascal@12756	8297 float Out, / (o) the resulting filtered vector */
pascal@12756	8298 float mem / (i/o) the filter state */
pascal@12756	8299 ){
pascal@12756	8300 int i;
pascal@12756	8301 float pi, po;
pascal@12756	8302
pascal@12756	8303 /* all-zero section*/
pascal@12756	8304
pascal@12756	8305 pi = &In[0];
pascal@12756	8306 po = &Out[0];
pascal@12756	8307 for (i=0; i<len; i++) {
pascal@12756	8308 po = hpo_zero_coefsTbl[0] (*pi);
pascal@12756	8309 po += hpo_zero_coefsTbl[1] mem[0];
pascal@12756	8310 po += hpo_zero_coefsTbl[2] mem[1];
pascal@12756	8311
pascal@12756	8312 mem[1] = mem[0];
pascal@12756	8313 mem[0] = *pi;
pascal@12756	8314 po++;
pascal@12756	8315 pi++;
pascal@12756	8316
pascal@12756	8317 }
pascal@12756	8318
pascal@12756	8319 /* all-pole section*/
pascal@12756	8320
pascal@12756	8321 po = &Out[0];
pascal@12756	8322 for (i=0; i<len; i++) {
pascal@12756	8323 po -= hpo_pole_coefsTbl[1] mem[2];
pascal@12756	8324 po -= hpo_pole_coefsTbl[2] mem[3];
pascal@12756	8325
pascal@12756	8326 mem[3] = mem[2];
pascal@12756	8327 mem[2] = *po;
pascal@12756	8328 po++;
pascal@12756	8329 }
pascal@12756	8330 }
pascal@12756	8331
pascal@12756	8332 A.31. iCBConstruct.h
pascal@12756	8333
pascal@12756	8334 /******************************************************************
pascal@12756	8335
pascal@12756	8336 iLBC Speech Coder ANSI-C Source Code
pascal@12756	8337
pascal@12756	8338 iCBConstruct.h
pascal@12756	8339
pascal@12756	8340 Copyright (C) The Internet Society (2004).
pascal@12756	8341 All Rights Reserved.
pascal@12756	8342
pascal@12756	8343
pascal@12756	8344
pascal@12756	8345
pascal@12756	8346 Andersen, et al. Experimental [Page 149]
pascal@12756	8347
pascal@12756	8348 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8349
pascal@12756	8350
pascal@12756	8351 ******************************************************************/
pascal@12756	8352
pascal@12756	8353 #ifndef __iLBC_ICBCONSTRUCT_H
pascal@12756	8354 #define __iLBC_ICBCONSTRUCT_H
pascal@12756	8355
pascal@12756	8356 void index_conv_enc(
pascal@12756	8357 int index / (i/o) Codebook indexes */
pascal@12756	8358 );
pascal@12756	8359
pascal@12756	8360 void index_conv_dec(
pascal@12756	8361 int index / (i/o) Codebook indexes */
pascal@12756	8362 );
pascal@12756	8363
pascal@12756	8364 void iCBConstruct(
pascal@12756	8365 float decvector, / (o) Decoded vector */
pascal@12756	8366 int index, / (i) Codebook indices */
pascal@12756	8367 int gain_index,/ (i) Gain quantization indices */
pascal@12756	8368 float mem, / (i) Buffer for codevector construction */
pascal@12756	8369 int lMem, /* (i) Length of buffer */
pascal@12756	8370 int veclen, /* (i) Length of vector */
pascal@12756	8371 int nStages /* (i) Number of codebook stages */
pascal@12756	8372 );
pascal@12756	8373
pascal@12756	8374 #endif
pascal@12756	8375
pascal@12756	8376 A.32. iCBConstruct.c
pascal@12756	8377
pascal@12756	8378 /******************************************************************
pascal@12756	8379
pascal@12756	8380 iLBC Speech Coder ANSI-C Source Code
pascal@12756	8381
pascal@12756	8382 iCBConstruct.c
pascal@12756	8383
pascal@12756	8384 Copyright (C) The Internet Society (2004).
pascal@12756	8385 All Rights Reserved.
pascal@12756	8386
pascal@12756	8387 ******************************************************************/
pascal@12756	8388
pascal@12756	8389 #include <math.h>
pascal@12756	8390
pascal@12756	8391 #include "iLBC_define.h"
pascal@12756	8392 #include "gainquant.h"
pascal@12756	8393 #include "getCBvec.h"
pascal@12756	8394
pascal@12756	8395 /----------------------------------------------------------------
pascal@12756	8396 * Convert the codebook indexes to make the search easier
pascal@12756	8397 ---------------------------------------------------------------/
pascal@12756	8398
pascal@12756	8399
pascal@12756	8400
pascal@12756	8401
pascal@12756	8402 Andersen, et al. Experimental [Page 150]
pascal@12756	8403
pascal@12756	8404 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8405
pascal@12756	8406
pascal@12756	8407 void index_conv_enc(
pascal@12756	8408 int index / (i/o) Codebook indexes */
pascal@12756	8409 ){
pascal@12756	8410 int k;
pascal@12756	8411
pascal@12756	8412 for (k=1; k<CB_NSTAGES; k++) {
pascal@12756	8413
pascal@12756	8414 if ((index[k]>=108)&&(index[k]<172)) {
pascal@12756	8415 index[k]-=64;
pascal@12756	8416 } else if (index[k]>=236) {
pascal@12756	8417 index[k]-=128;
pascal@12756	8418 } else {
pascal@12756	8419 /* ERROR */
pascal@12756	8420 }
pascal@12756	8421 }
pascal@12756	8422 }
pascal@12756	8423
pascal@12756	8424 void index_conv_dec(
pascal@12756	8425 int index / (i/o) Codebook indexes */
pascal@12756	8426 ){
pascal@12756	8427 int k;
pascal@12756	8428
pascal@12756	8429 for (k=1; k<CB_NSTAGES; k++) {
pascal@12756	8430
pascal@12756	8431 if ((index[k]>=44)&&(index[k]<108)) {
pascal@12756	8432 index[k]+=64;
pascal@12756	8433 } else if ((index[k]>=108)&&(index[k]<128)) {
pascal@12756	8434 index[k]+=128;
pascal@12756	8435 } else {
pascal@12756	8436 /* ERROR */
pascal@12756	8437 }
pascal@12756	8438 }
pascal@12756	8439 }
pascal@12756	8440
pascal@12756	8441 /----------------------------------------------------------------
pascal@12756	8442 * Construct decoded vector from codebook and gains.
pascal@12756	8443 ---------------------------------------------------------------/
pascal@12756	8444
pascal@12756	8445 void iCBConstruct(
pascal@12756	8446 float decvector, / (o) Decoded vector */
pascal@12756	8447 int index, / (i) Codebook indices */
pascal@12756	8448 int gain_index,/ (i) Gain quantization indices */
pascal@12756	8449 float mem, / (i) Buffer for codevector construction */
pascal@12756	8450 int lMem, /* (i) Length of buffer */
pascal@12756	8451 int veclen, /* (i) Length of vector */
pascal@12756	8452 int nStages /* (i) Number of codebook stages */
pascal@12756	8453 ){
pascal@12756	8454 int j,k;
pascal@12756	8455
pascal@12756	8456
pascal@12756	8457
pascal@12756	8458 Andersen, et al. Experimental [Page 151]
pascal@12756	8459
pascal@12756	8460 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8461
pascal@12756	8462
pascal@12756	8463 float gain[CB_NSTAGES];
pascal@12756	8464 float cbvec[SUBL];
pascal@12756	8465
pascal@12756	8466 /* gain de-quantization */
pascal@12756	8467
pascal@12756	8468 gain[0] = gaindequant(gain_index[0], 1.0, 32);
pascal@12756	8469 if (nStages > 1) {
pascal@12756	8470 gain[1] = gaindequant(gain_index[1],
pascal@12756	8471 (float)fabs(gain[0]), 16);
pascal@12756	8472 }
pascal@12756	8473 if (nStages > 2) {
pascal@12756	8474 gain[2] = gaindequant(gain_index[2],
pascal@12756	8475 (float)fabs(gain[1]), 8);
pascal@12756	8476 }
pascal@12756	8477
pascal@12756	8478 /* codebook vector construction and construction of
pascal@12756	8479 total vector */
pascal@12756	8480
pascal@12756	8481 getCBvec(cbvec, mem, index[0], lMem, veclen);
pascal@12756	8482 for (j=0;j<veclen;j++){
pascal@12756	8483 decvector[j] = gain[0]*cbvec[j];
pascal@12756	8484 }
pascal@12756	8485 if (nStages > 1) {
pascal@12756	8486 for (k=1; k<nStages; k++) {
pascal@12756	8487 getCBvec(cbvec, mem, index[k], lMem, veclen);
pascal@12756	8488 for (j=0;j<veclen;j++) {
pascal@12756	8489 decvector[j] += gain[k]*cbvec[j];
pascal@12756	8490 }
pascal@12756	8491 }
pascal@12756	8492 }
pascal@12756	8493 }
pascal@12756	8494
pascal@12756	8495 A.33. iCBSearch.h
pascal@12756	8496
pascal@12756	8497 /******************************************************************
pascal@12756	8498
pascal@12756	8499 iLBC Speech Coder ANSI-C Source Code
pascal@12756	8500
pascal@12756	8501 iCBSearch.h
pascal@12756	8502
pascal@12756	8503 Copyright (C) The Internet Society (2004).
pascal@12756	8504 All Rights Reserved.
pascal@12756	8505
pascal@12756	8506 ******************************************************************/
pascal@12756	8507
pascal@12756	8508 #ifndef __iLBC_ICBSEARCH_H
pascal@12756	8509 #define __iLBC_ICBSEARCH_H
pascal@12756	8510
pascal@12756	8511
pascal@12756	8512
pascal@12756	8513
pascal@12756	8514 Andersen, et al. Experimental [Page 152]
pascal@12756	8515
pascal@12756	8516 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8517
pascal@12756	8518
pascal@12756	8519 void iCBSearch(
pascal@12756	8520 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	8521 /* (i) the encoder state structure */
pascal@12756	8522 int index, / (o) Codebook indices */
pascal@12756	8523 int gain_index,/ (o) Gain quantization indices */
pascal@12756	8524 float intarget,/ (i) Target vector for encoding */
pascal@12756	8525 float mem, / (i) Buffer for codebook construction */
pascal@12756	8526 int lMem, /* (i) Length of buffer */
pascal@12756	8527 int lTarget, /* (i) Length of vector */
pascal@12756	8528 int nStages, /* (i) Number of codebook stages */
pascal@12756	8529 float weightDenum, / (i) weighting filter coefficients */
pascal@12756	8530 float weightState, / (i) weighting filter state */
pascal@12756	8531 int block /* (i) the sub-block number */
pascal@12756	8532 );
pascal@12756	8533
pascal@12756	8534 #endif
pascal@12756	8535
pascal@12756	8536 A.34. iCBSearch.c
pascal@12756	8537
pascal@12756	8538 /******************************************************************
pascal@12756	8539
pascal@12756	8540 iLBC Speech Coder ANSI-C Source Code
pascal@12756	8541
pascal@12756	8542 iCBSearch.c
pascal@12756	8543
pascal@12756	8544 Copyright (C) The Internet Society (2004).
pascal@12756	8545 All Rights Reserved.
pascal@12756	8546
pascal@12756	8547 ******************************************************************/
pascal@12756	8548
pascal@12756	8549 #include <math.h>
pascal@12756	8550 #include <string.h>
pascal@12756	8551
pascal@12756	8552 #include "iLBC_define.h"
pascal@12756	8553 #include "gainquant.h"
pascal@12756	8554 #include "createCB.h"
pascal@12756	8555 #include "filter.h"
pascal@12756	8556 #include "constants.h"
pascal@12756	8557
pascal@12756	8558 /----------------------------------------------------------------
pascal@12756	8559 * Search routine for codebook encoding and gain quantization.
pascal@12756	8560 ---------------------------------------------------------------/
pascal@12756	8561
pascal@12756	8562 void iCBSearch(
pascal@12756	8563 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	8564 /* (i) the encoder state structure */
pascal@12756	8565 int index, / (o) Codebook indices */
pascal@12756	8566 int gain_index,/ (o) Gain quantization indices */
pascal@12756	8567
pascal@12756	8568
pascal@12756	8569
pascal@12756	8570 Andersen, et al. Experimental [Page 153]
pascal@12756	8571
pascal@12756	8572 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8573
pascal@12756	8574
pascal@12756	8575 float intarget,/ (i) Target vector for encoding */
pascal@12756	8576 float mem, / (i) Buffer for codebook construction */
pascal@12756	8577 int lMem, /* (i) Length of buffer */
pascal@12756	8578 int lTarget, /* (i) Length of vector */
pascal@12756	8579 int nStages, /* (i) Number of codebook stages */
pascal@12756	8580 float weightDenum, / (i) weighting filter coefficients */
pascal@12756	8581 float weightState, / (i) weighting filter state */
pascal@12756	8582 int block /* (i) the sub-block number */
pascal@12756	8583 ){
pascal@12756	8584 int i, j, icount, stage, best_index, range, counter;
pascal@12756	8585 float max_measure, gain, measure, crossDot, ftmp;
pascal@12756	8586 float gains[CB_NSTAGES];
pascal@12756	8587 float target[SUBL];
pascal@12756	8588 int base_index, sInd, eInd, base_size;
pascal@12756	8589 int sIndAug=0, eIndAug=0;
pascal@12756	8590 float buf[CB_MEML+SUBL+2*LPC_FILTERORDER];
pascal@12756	8591 float invenergy[CB_EXPAND128], energy[CB_EXPAND128];
pascal@12756	8592 float pp, ppi=0, ppo=0, ppe=0;
pascal@12756	8593 float cbvectors[CB_MEML];
pascal@12756	8594 float tene, cene, cvec[SUBL];
pascal@12756	8595 float aug_vec[SUBL];
pascal@12756	8596
pascal@12756	8597 memset(cvec,0,SUBL*sizeof(float));
pascal@12756	8598
pascal@12756	8599 /* Determine size of codebook sections */
pascal@12756	8600
pascal@12756	8601 base_size=lMem-lTarget+1;
pascal@12756	8602
pascal@12756	8603 if (lTarget==SUBL) {
pascal@12756	8604 base_size=lMem-lTarget+1+lTarget/2;
pascal@12756	8605 }
pascal@12756	8606
pascal@12756	8607 /* setup buffer for weighting */
pascal@12756	8608
pascal@12756	8609 memcpy(buf,weightState,sizeof(float)*LPC_FILTERORDER);
pascal@12756	8610 memcpy(buf+LPC_FILTERORDER,mem,lMem*sizeof(float));
pascal@12756	8611 memcpy(buf+LPC_FILTERORDER+lMem,intarget,lTarget*sizeof(float));
pascal@12756	8612
pascal@12756	8613 /* weighting */
pascal@12756	8614
pascal@12756	8615 AllPoleFilter(buf+LPC_FILTERORDER, weightDenum,
pascal@12756	8616 lMem+lTarget, LPC_FILTERORDER);
pascal@12756	8617
pascal@12756	8618 /* Construct the codebook and target needed */
pascal@12756	8619
pascal@12756	8620 memcpy(target, buf+LPC_FILTERORDER+lMem, lTarget*sizeof(float));
pascal@12756	8621
pascal@12756	8622 tene=0.0;
pascal@12756	8623
pascal@12756	8624
pascal@12756	8625
pascal@12756	8626 Andersen, et al. Experimental [Page 154]
pascal@12756	8627
pascal@12756	8628 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8629
pascal@12756	8630
pascal@12756	8631 for (i=0; i<lTarget; i++) {
pascal@12756	8632 tene+=target[i]*target[i];
pascal@12756	8633 }
pascal@12756	8634
pascal@12756	8635 /* Prepare search over one more codebook section. This section
pascal@12756	8636 is created by filtering the original buffer with a filter. */
pascal@12756	8637
pascal@12756	8638 filteredCBvecs(cbvectors, buf+LPC_FILTERORDER, lMem);
pascal@12756	8639
pascal@12756	8640 /* The Main Loop over stages */
pascal@12756	8641
pascal@12756	8642 for (stage=0; stage<nStages; stage++) {
pascal@12756	8643
pascal@12756	8644 range = search_rangeTbl[block][stage];
pascal@12756	8645
pascal@12756	8646 /* initialize search measure */
pascal@12756	8647
pascal@12756	8648 max_measure = (float)-10000000.0;
pascal@12756	8649 gain = (float)0.0;
pascal@12756	8650 best_index = 0;
pascal@12756	8651
pascal@12756	8652 /* Compute cross dot product between the target
pascal@12756	8653 and the CB memory */
pascal@12756	8654
pascal@12756	8655 crossDot=0.0;
pascal@12756	8656 pp=buf+LPC_FILTERORDER+lMem-lTarget;
pascal@12756	8657 for (j=0; j<lTarget; j++) {
pascal@12756	8658 crossDot += target[j](pp++);
pascal@12756	8659 }
pascal@12756	8660
pascal@12756	8661 if (stage==0) {
pascal@12756	8662
pascal@12756	8663 /* Calculate energy in the first block of
pascal@12756	8664 'lTarget' samples. */
pascal@12756	8665 ppe = energy;
pascal@12756	8666 ppi = buf+LPC_FILTERORDER+lMem-lTarget-1;
pascal@12756	8667 ppo = buf+LPC_FILTERORDER+lMem-1;
pascal@12756	8668
pascal@12756	8669 *ppe=0.0;
pascal@12756	8670 pp=buf+LPC_FILTERORDER+lMem-lTarget;
pascal@12756	8671 for (j=0; j<lTarget; j++) {
pascal@12756	8672 ppe+=(pp)(pp++);
pascal@12756	8673 }
pascal@12756	8674
pascal@12756	8675 if (*ppe>0.0) {
pascal@12756	8676 invenergy[0] = (float) 1.0 / (*ppe + EPS);
pascal@12756	8677 } else {
pascal@12756	8678 invenergy[0] = (float) 0.0;
pascal@12756	8679
pascal@12756	8680
pascal@12756	8681
pascal@12756	8682 Andersen, et al. Experimental [Page 155]
pascal@12756	8683
pascal@12756	8684 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8685
pascal@12756	8686
pascal@12756	8687 }
pascal@12756	8688 ppe++;
pascal@12756	8689
pascal@12756	8690 measure=(float)-10000000.0;
pascal@12756	8691
pascal@12756	8692 if (crossDot > 0.0) {
pascal@12756	8693 measure = crossDotcrossDotinvenergy[0];
pascal@12756	8694 }
pascal@12756	8695 }
pascal@12756	8696 else {
pascal@12756	8697 measure = crossDotcrossDotinvenergy[0];
pascal@12756	8698 }
pascal@12756	8699
pascal@12756	8700 /* check if measure is better */
pascal@12756	8701 ftmp = crossDot*invenergy[0];
pascal@12756	8702
pascal@12756	8703 if ((measure>max_measure) && (fabs(ftmp)<CB_MAXGAIN)) {
pascal@12756	8704 best_index = 0;
pascal@12756	8705 max_measure = measure;
pascal@12756	8706 gain = ftmp;
pascal@12756	8707 }
pascal@12756	8708
pascal@12756	8709 /* loop over the main first codebook section,
pascal@12756	8710 full search */
pascal@12756	8711
pascal@12756	8712 for (icount=1; icount<range; icount++) {
pascal@12756	8713
pascal@12756	8714 /* calculate measure */
pascal@12756	8715
pascal@12756	8716 crossDot=0.0;
pascal@12756	8717 pp = buf+LPC_FILTERORDER+lMem-lTarget-icount;
pascal@12756	8718
pascal@12756	8719 for (j=0; j<lTarget; j++) {
pascal@12756	8720 crossDot += target[j](pp++);
pascal@12756	8721 }
pascal@12756	8722
pascal@12756	8723 if (stage==0) {
pascal@12756	8724 ppe++ = energy[icount-1] + (ppi)(ppi) -
pascal@12756	8725 (ppo)(*ppo);
pascal@12756	8726 ppo--;
pascal@12756	8727 ppi--;
pascal@12756	8728
pascal@12756	8729 if (energy[icount]>0.0) {
pascal@12756	8730 invenergy[icount] =
pascal@12756	8731 (float)1.0/(energy[icount]+EPS);
pascal@12756	8732 } else {
pascal@12756	8733 invenergy[icount] = (float) 0.0;
pascal@12756	8734 }
pascal@12756	8735
pascal@12756	8736
pascal@12756	8737
pascal@12756	8738 Andersen, et al. Experimental [Page 156]
pascal@12756	8739
pascal@12756	8740 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8741
pascal@12756	8742
pascal@12756	8743 measure=(float)-10000000.0;
pascal@12756	8744
pascal@12756	8745 if (crossDot > 0.0) {
pascal@12756	8746 measure = crossDotcrossDotinvenergy[icount];
pascal@12756	8747 }
pascal@12756	8748 }
pascal@12756	8749 else {
pascal@12756	8750 measure = crossDotcrossDotinvenergy[icount];
pascal@12756	8751 }
pascal@12756	8752
pascal@12756	8753 /* check if measure is better */
pascal@12756	8754 ftmp = crossDot*invenergy[icount];
pascal@12756	8755
pascal@12756	8756 if ((measure>max_measure) && (fabs(ftmp)<CB_MAXGAIN)) {
pascal@12756	8757 best_index = icount;
pascal@12756	8758 max_measure = measure;
pascal@12756	8759 gain = ftmp;
pascal@12756	8760 }
pascal@12756	8761 }
pascal@12756	8762
pascal@12756	8763 /* Loop over augmented part in the first codebook
pascal@12756	8764 * section, full search.
pascal@12756	8765 * The vectors are interpolated.
pascal@12756	8766 */
pascal@12756	8767
pascal@12756	8768 if (lTarget==SUBL) {
pascal@12756	8769
pascal@12756	8770 /* Search for best possible cb vector and
pascal@12756	8771 compute the CB-vectors' energy. */
pascal@12756	8772 searchAugmentedCB(20, 39, stage, base_size-lTarget/2,
pascal@12756	8773 target, buf+LPC_FILTERORDER+lMem,
pascal@12756	8774 &max_measure, &best_index, &gain, energy,
pascal@12756	8775 invenergy);
pascal@12756	8776 }
pascal@12756	8777
pascal@12756	8778 /* set search range for following codebook sections */
pascal@12756	8779
pascal@12756	8780 base_index=best_index;
pascal@12756	8781
pascal@12756	8782 /* unrestricted search */
pascal@12756	8783
pascal@12756	8784 if (CB_RESRANGE == -1) {
pascal@12756	8785 sInd=0;
pascal@12756	8786 eInd=range-1;
pascal@12756	8787 sIndAug=20;
pascal@12756	8788 eIndAug=39;
pascal@12756	8789 }
pascal@12756	8790
pascal@12756	8791
pascal@12756	8792
pascal@12756	8793
pascal@12756	8794 Andersen, et al. Experimental [Page 157]
pascal@12756	8795
pascal@12756	8796 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8797
pascal@12756	8798
pascal@12756	8799 /* restricted search around best index from first
pascal@12756	8800 codebook section */
pascal@12756	8801
pascal@12756	8802 else {
pascal@12756	8803 /* Initialize search indices */
pascal@12756	8804 sIndAug=0;
pascal@12756	8805 eIndAug=0;
pascal@12756	8806 sInd=base_index-CB_RESRANGE/2;
pascal@12756	8807 eInd=sInd+CB_RESRANGE;
pascal@12756	8808
pascal@12756	8809 if (lTarget==SUBL) {
pascal@12756	8810
pascal@12756	8811 if (sInd<0) {
pascal@12756	8812
pascal@12756	8813 sIndAug = 40 + sInd;
pascal@12756	8814 eIndAug = 39;
pascal@12756	8815 sInd=0;
pascal@12756	8816
pascal@12756	8817 } else if ( base_index < (base_size-20) ) {
pascal@12756	8818
pascal@12756	8819 if (eInd > range) {
pascal@12756	8820 sInd -= (eInd-range);
pascal@12756	8821 eInd = range;
pascal@12756	8822 }
pascal@12756	8823 } else { /* base_index >= (base_size-20) */
pascal@12756	8824
pascal@12756	8825 if (sInd < (base_size-20)) {
pascal@12756	8826 sIndAug = 20;
pascal@12756	8827 sInd = 0;
pascal@12756	8828 eInd = 0;
pascal@12756	8829 eIndAug = 19 + CB_RESRANGE;
pascal@12756	8830
pascal@12756	8831 if(eIndAug > 39) {
pascal@12756	8832 eInd = eIndAug-39;
pascal@12756	8833 eIndAug = 39;
pascal@12756	8834 }
pascal@12756	8835 } else {
pascal@12756	8836 sIndAug = 20 + sInd - (base_size-20);
pascal@12756	8837 eIndAug = 39;
pascal@12756	8838 sInd = 0;
pascal@12756	8839 eInd = CB_RESRANGE - (eIndAug-sIndAug+1);
pascal@12756	8840 }
pascal@12756	8841 }
pascal@12756	8842
pascal@12756	8843 } else { /* lTarget = 22 or 23 */
pascal@12756	8844
pascal@12756	8845 if (sInd < 0) {
pascal@12756	8846 eInd -= sInd;
pascal@12756	8847
pascal@12756	8848
pascal@12756	8849
pascal@12756	8850 Andersen, et al. Experimental [Page 158]
pascal@12756	8851
pascal@12756	8852 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8853
pascal@12756	8854
pascal@12756	8855 sInd = 0;
pascal@12756	8856 }
pascal@12756	8857
pascal@12756	8858 if(eInd > range) {
pascal@12756	8859 sInd -= (eInd - range);
pascal@12756	8860 eInd = range;
pascal@12756	8861 }
pascal@12756	8862 }
pascal@12756	8863 }
pascal@12756	8864
pascal@12756	8865 /* search of higher codebook section */
pascal@12756	8866
pascal@12756	8867 /* index search range */
pascal@12756	8868 counter = sInd;
pascal@12756	8869 sInd += base_size;
pascal@12756	8870 eInd += base_size;
pascal@12756	8871
pascal@12756	8872
pascal@12756	8873 if (stage==0) {
pascal@12756	8874 ppe = energy+base_size;
pascal@12756	8875 *ppe=0.0;
pascal@12756	8876
pascal@12756	8877 pp=cbvectors+lMem-lTarget;
pascal@12756	8878 for (j=0; j<lTarget; j++) {
pascal@12756	8879 ppe+=(pp)(pp++);
pascal@12756	8880 }
pascal@12756	8881
pascal@12756	8882 ppi = cbvectors + lMem - 1 - lTarget;
pascal@12756	8883 ppo = cbvectors + lMem - 1;
pascal@12756	8884
pascal@12756	8885 for (j=0; j<(range-1); j++) {
pascal@12756	8886 (ppe+1) = ppe + (ppi)(ppi) - (ppo)(ppo);
pascal@12756	8887 ppo--;
pascal@12756	8888 ppi--;
pascal@12756	8889 ppe++;
pascal@12756	8890 }
pascal@12756	8891 }
pascal@12756	8892
pascal@12756	8893 /* loop over search range */
pascal@12756	8894
pascal@12756	8895 for (icount=sInd; icount<eInd; icount++) {
pascal@12756	8896
pascal@12756	8897 /* calculate measure */
pascal@12756	8898
pascal@12756	8899 crossDot=0.0;
pascal@12756	8900 pp=cbvectors + lMem - (counter++) - lTarget;
pascal@12756	8901
pascal@12756	8902 for (j=0;j<lTarget;j++) {
pascal@12756	8903
pascal@12756	8904
pascal@12756	8905
pascal@12756	8906 Andersen, et al. Experimental [Page 159]
pascal@12756	8907
pascal@12756	8908 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8909
pascal@12756	8910
pascal@12756	8911 crossDot += target[j](pp++);
pascal@12756	8912 }
pascal@12756	8913
pascal@12756	8914 if (energy[icount]>0.0) {
pascal@12756	8915 invenergy[icount] =(float)1.0/(energy[icount]+EPS);
pascal@12756	8916 } else {
pascal@12756	8917 invenergy[icount] =(float)0.0;
pascal@12756	8918 }
pascal@12756	8919
pascal@12756	8920 if (stage==0) {
pascal@12756	8921
pascal@12756	8922 measure=(float)-10000000.0;
pascal@12756	8923
pascal@12756	8924 if (crossDot > 0.0) {
pascal@12756	8925 measure = crossDotcrossDot
pascal@12756	8926 invenergy[icount];
pascal@12756	8927 }
pascal@12756	8928 }
pascal@12756	8929 else {
pascal@12756	8930 measure = crossDotcrossDotinvenergy[icount];
pascal@12756	8931 }
pascal@12756	8932
pascal@12756	8933 /* check if measure is better */
pascal@12756	8934 ftmp = crossDot*invenergy[icount];
pascal@12756	8935
pascal@12756	8936 if ((measure>max_measure) && (fabs(ftmp)<CB_MAXGAIN)) {
pascal@12756	8937 best_index = icount;
pascal@12756	8938 max_measure = measure;
pascal@12756	8939 gain = ftmp;
pascal@12756	8940 }
pascal@12756	8941 }
pascal@12756	8942
pascal@12756	8943 /* Search the augmented CB inside the limited range. */
pascal@12756	8944
pascal@12756	8945 if ((lTarget==SUBL)&&(sIndAug!=0)) {
pascal@12756	8946 searchAugmentedCB(sIndAug, eIndAug, stage,
pascal@12756	8947 2*base_size-20, target, cbvectors+lMem,
pascal@12756	8948 &max_measure, &best_index, &gain, energy,
pascal@12756	8949 invenergy);
pascal@12756	8950 }
pascal@12756	8951
pascal@12756	8952 /* record best index */
pascal@12756	8953
pascal@12756	8954 index[stage] = best_index;
pascal@12756	8955
pascal@12756	8956 /* gain quantization */
pascal@12756	8957
pascal@12756	8958 if (stage==0){
pascal@12756	8959
pascal@12756	8960
pascal@12756	8961
pascal@12756	8962 Andersen, et al. Experimental [Page 160]
pascal@12756	8963
pascal@12756	8964 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	8965
pascal@12756	8966
pascal@12756	8967
pascal@12756	8968 if (gain<0.0){
pascal@12756	8969 gain = 0.0;
pascal@12756	8970 }
pascal@12756	8971
pascal@12756	8972 if (gain>CB_MAXGAIN) {
pascal@12756	8973 gain = (float)CB_MAXGAIN;
pascal@12756	8974 }
pascal@12756	8975 gain = gainquant(gain, 1.0, 32, &gain_index[stage]);
pascal@12756	8976 }
pascal@12756	8977 else {
pascal@12756	8978 if (stage==1) {
pascal@12756	8979 gain = gainquant(gain, (float)fabs(gains[stage-1]),
pascal@12756	8980 16, &gain_index[stage]);
pascal@12756	8981 } else {
pascal@12756	8982 gain = gainquant(gain, (float)fabs(gains[stage-1]),
pascal@12756	8983 8, &gain_index[stage]);
pascal@12756	8984 }
pascal@12756	8985 }
pascal@12756	8986
pascal@12756	8987 /* Extract the best (according to measure)
pascal@12756	8988 codebook vector */
pascal@12756	8989
pascal@12756	8990 if (lTarget==(STATE_LEN-iLBCenc_inst->state_short_len)) {
pascal@12756	8991
pascal@12756	8992 if (index[stage]<base_size) {
pascal@12756	8993 pp=buf+LPC_FILTERORDER+lMem-lTarget-index[stage];
pascal@12756	8994 } else {
pascal@12756	8995 pp=cbvectors+lMem-lTarget-
pascal@12756	8996 index[stage]+base_size;
pascal@12756	8997 }
pascal@12756	8998 } else {
pascal@12756	8999
pascal@12756	9000 if (index[stage]<base_size) {
pascal@12756	9001 if (index[stage]<(base_size-20)) {
pascal@12756	9002 pp=buf+LPC_FILTERORDER+lMem-
pascal@12756	9003 lTarget-index[stage];
pascal@12756	9004 } else {
pascal@12756	9005 createAugmentedVec(index[stage]-base_size+40,
pascal@12756	9006 buf+LPC_FILTERORDER+lMem,aug_vec);
pascal@12756	9007 pp=aug_vec;
pascal@12756	9008 }
pascal@12756	9009 } else {
pascal@12756	9010 int filterno, position;
pascal@12756	9011
pascal@12756	9012 filterno=index[stage]/base_size;
pascal@12756	9013 position=index[stage]-filterno*base_size;
pascal@12756	9014
pascal@12756	9015
pascal@12756	9016
pascal@12756	9017
pascal@12756	9018 Andersen, et al. Experimental [Page 161]
pascal@12756	9019
pascal@12756	9020 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9021
pascal@12756	9022
pascal@12756	9023
pascal@12756	9024 if (position<(base_size-20)) {
pascal@12756	9025 pp=cbvectors+filterno*lMem-lTarget-
pascal@12756	9026 index[stage]+filterno*base_size;
pascal@12756	9027 } else {
pascal@12756	9028 createAugmentedVec(
pascal@12756	9029 index[stage]-(filterno+1)*base_size+40,
pascal@12756	9030 cbvectors+filterno*lMem,aug_vec);
pascal@12756	9031 pp=aug_vec;
pascal@12756	9032 }
pascal@12756	9033 }
pascal@12756	9034 }
pascal@12756	9035
pascal@12756	9036 /* Subtract the best codebook vector, according
pascal@12756	9037 to measure, from the target vector */
pascal@12756	9038
pascal@12756	9039 for (j=0;j<lTarget;j++) {
pascal@12756	9040 cvec[j] += gain(pp);
pascal@12756	9041 target[j] -= gain(pp++);
pascal@12756	9042 }
pascal@12756	9043
pascal@12756	9044 /* record quantized gain */
pascal@12756	9045
pascal@12756	9046 gains[stage]=gain;
pascal@12756	9047
pascal@12756	9048 }/* end of Main Loop. for (stage=0;... */
pascal@12756	9049
pascal@12756	9050 /* Gain adjustment for energy matching */
pascal@12756	9051 cene=0.0;
pascal@12756	9052 for (i=0; i<lTarget; i++) {
pascal@12756	9053 cene+=cvec[i]*cvec[i];
pascal@12756	9054 }
pascal@12756	9055 j=gain_index[0];
pascal@12756	9056
pascal@12756	9057 for (i=gain_index[0]; i<32; i++) {
pascal@12756	9058 ftmp=cenegain_sq5Tbl[i]gain_sq5Tbl[i];
pascal@12756	9059
pascal@12756	9060 if ((ftmp<(tenegains[0]gains[0])) &&
pascal@12756	9061 (gain_sq5Tbl[j]<(2.0*gains[0]))) {
pascal@12756	9062 j=i;
pascal@12756	9063 }
pascal@12756	9064 }
pascal@12756	9065 gain_index[0]=j;
pascal@12756	9066 }
pascal@12756	9067
pascal@12756	9068
pascal@12756	9069
pascal@12756	9070
pascal@12756	9071
pascal@12756	9072
pascal@12756	9073
pascal@12756	9074 Andersen, et al. Experimental [Page 162]
pascal@12756	9075
pascal@12756	9076 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9077
pascal@12756	9078
pascal@12756	9079 A.35. LPCdecode.h
pascal@12756	9080
pascal@12756	9081 /******************************************************************
pascal@12756	9082
pascal@12756	9083 iLBC Speech Coder ANSI-C Source Code
pascal@12756	9084
pascal@12756	9085 LPC_decode.h
pascal@12756	9086
pascal@12756	9087 Copyright (C) The Internet Society (2004).
pascal@12756	9088 All Rights Reserved.
pascal@12756	9089
pascal@12756	9090 ******************************************************************/
pascal@12756	9091
pascal@12756	9092 #ifndef __iLBC_LPC_DECODE_H
pascal@12756	9093 #define __iLBC_LPC_DECODE_H
pascal@12756	9094
pascal@12756	9095 void LSFinterpolate2a_dec(
pascal@12756	9096 float a, / (o) lpc coefficients for a sub-frame */
pascal@12756	9097 float lsf1, / (i) first lsf coefficient vector */
pascal@12756	9098 float lsf2, / (i) second lsf coefficient vector */
pascal@12756	9099 float coef, /* (i) interpolation weight */
pascal@12756	9100 int length /* (i) length of lsf vectors */
pascal@12756	9101 );
pascal@12756	9102
pascal@12756	9103 void SimplelsfDEQ(
pascal@12756	9104 float lsfdeq, / (o) dequantized lsf coefficients */
pascal@12756	9105 int index, / (i) quantization index */
pascal@12756	9106 int lpc_n /* (i) number of LPCs */
pascal@12756	9107 );
pascal@12756	9108
pascal@12756	9109 void DecoderInterpolateLSF(
pascal@12756	9110 float syntdenum, / (o) synthesis filter coefficients */
pascal@12756	9111 float weightdenum, / (o) weighting denumerator
pascal@12756	9112 coefficients */
pascal@12756	9113 float lsfdeq, / (i) dequantized lsf coefficients */
pascal@12756	9114 int length, /* (i) length of lsf coefficient vector */
pascal@12756	9115 iLBC_Dec_Inst_t *iLBCdec_inst
pascal@12756	9116 /* (i) the decoder state structure */
pascal@12756	9117 );
pascal@12756	9118
pascal@12756	9119 #endif
pascal@12756	9120
pascal@12756	9121
pascal@12756	9122
pascal@12756	9123
pascal@12756	9124
pascal@12756	9125
pascal@12756	9126
pascal@12756	9127
pascal@12756	9128
pascal@12756	9129
pascal@12756	9130 Andersen, et al. Experimental [Page 163]
pascal@12756	9131
pascal@12756	9132 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9133
pascal@12756	9134
pascal@12756	9135 A.36. LPCdecode.c
pascal@12756	9136
pascal@12756	9137 /******************************************************************
pascal@12756	9138
pascal@12756	9139 iLBC Speech Coder ANSI-C Source Code
pascal@12756	9140
pascal@12756	9141 LPC_decode.c
pascal@12756	9142
pascal@12756	9143 Copyright (C) The Internet Society (2004).
pascal@12756	9144 All Rights Reserved.
pascal@12756	9145
pascal@12756	9146 ******************************************************************/
pascal@12756	9147
pascal@12756	9148 #include <math.h>
pascal@12756	9149 #include <string.h>
pascal@12756	9150
pascal@12756	9151 #include "helpfun.h"
pascal@12756	9152 #include "lsf.h"
pascal@12756	9153 #include "iLBC_define.h"
pascal@12756	9154 #include "constants.h"
pascal@12756	9155
pascal@12756	9156 /---------------------------------------------------------------
pascal@12756	9157 * interpolation of lsf coefficients for the decoder
pascal@12756	9158 --------------------------------------------------------------/
pascal@12756	9159
pascal@12756	9160 void LSFinterpolate2a_dec(
pascal@12756	9161 float a, / (o) lpc coefficients for a sub-frame */
pascal@12756	9162 float lsf1, / (i) first lsf coefficient vector */
pascal@12756	9163 float lsf2, / (i) second lsf coefficient vector */
pascal@12756	9164 float coef, /* (i) interpolation weight */
pascal@12756	9165 int length /* (i) length of lsf vectors */
pascal@12756	9166 ){
pascal@12756	9167 float lsftmp[LPC_FILTERORDER];
pascal@12756	9168
pascal@12756	9169 interpolate(lsftmp, lsf1, lsf2, coef, length);
pascal@12756	9170 lsf2a(a, lsftmp);
pascal@12756	9171 }
pascal@12756	9172
pascal@12756	9173 /---------------------------------------------------------------
pascal@12756	9174 * obtain dequantized lsf coefficients from quantization index
pascal@12756	9175 --------------------------------------------------------------/
pascal@12756	9176
pascal@12756	9177 void SimplelsfDEQ(
pascal@12756	9178 float lsfdeq, / (o) dequantized lsf coefficients */
pascal@12756	9179 int index, / (i) quantization index */
pascal@12756	9180 int lpc_n /* (i) number of LPCs */
pascal@12756	9181 ){
pascal@12756	9182 int i, j, pos, cb_pos;
pascal@12756	9183
pascal@12756	9184
pascal@12756	9185
pascal@12756	9186 Andersen, et al. Experimental [Page 164]
pascal@12756	9187
pascal@12756	9188 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9189
pascal@12756	9190
pascal@12756	9191 /* decode first LSF */
pascal@12756	9192
pascal@12756	9193 pos = 0;
pascal@12756	9194 cb_pos = 0;
pascal@12756	9195 for (i = 0; i < LSF_NSPLIT; i++) {
pascal@12756	9196 for (j = 0; j < dim_lsfCbTbl[i]; j++) {
pascal@12756	9197 lsfdeq[pos + j] = lsfCbTbl[cb_pos +
pascal@12756	9198 (long)(index[i])*dim_lsfCbTbl[i] + j];
pascal@12756	9199 }
pascal@12756	9200 pos += dim_lsfCbTbl[i];
pascal@12756	9201 cb_pos += size_lsfCbTbl[i]*dim_lsfCbTbl[i];
pascal@12756	9202 }
pascal@12756	9203
pascal@12756	9204 if (lpc_n>1) {
pascal@12756	9205
pascal@12756	9206 /* decode last LSF */
pascal@12756	9207
pascal@12756	9208 pos = 0;
pascal@12756	9209 cb_pos = 0;
pascal@12756	9210 for (i = 0; i < LSF_NSPLIT; i++) {
pascal@12756	9211 for (j = 0; j < dim_lsfCbTbl[i]; j++) {
pascal@12756	9212 lsfdeq[LPC_FILTERORDER + pos + j] =
pascal@12756	9213 lsfCbTbl[cb_pos +
pascal@12756	9214 (long)(index[LSF_NSPLIT + i])*
pascal@12756	9215 dim_lsfCbTbl[i] + j];
pascal@12756	9216 }
pascal@12756	9217 pos += dim_lsfCbTbl[i];
pascal@12756	9218 cb_pos += size_lsfCbTbl[i]*dim_lsfCbTbl[i];
pascal@12756	9219 }
pascal@12756	9220 }
pascal@12756	9221 }
pascal@12756	9222
pascal@12756	9223 /----------------------------------------------------------------
pascal@12756	9224 * obtain synthesis and weighting filters form lsf coefficients
pascal@12756	9225 ---------------------------------------------------------------/
pascal@12756	9226
pascal@12756	9227 void DecoderInterpolateLSF(
pascal@12756	9228 float syntdenum, / (o) synthesis filter coefficients */
pascal@12756	9229 float weightdenum, / (o) weighting denumerator
pascal@12756	9230 coefficients */
pascal@12756	9231 float lsfdeq, / (i) dequantized lsf coefficients */
pascal@12756	9232 int length, /* (i) length of lsf coefficient vector */
pascal@12756	9233 iLBC_Dec_Inst_t *iLBCdec_inst
pascal@12756	9234 /* (i) the decoder state structure */
pascal@12756	9235 ){
pascal@12756	9236 int i, pos, lp_length;
pascal@12756	9237 float lp[LPC_FILTERORDER + 1], *lsfdeq2;
pascal@12756	9238
pascal@12756	9239
pascal@12756	9240
pascal@12756	9241
pascal@12756	9242 Andersen, et al. Experimental [Page 165]
pascal@12756	9243
pascal@12756	9244 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9245
pascal@12756	9246
pascal@12756	9247 lsfdeq2 = lsfdeq + length;
pascal@12756	9248 lp_length = length + 1;
pascal@12756	9249
pascal@12756	9250 if (iLBCdec_inst->mode==30) {
pascal@12756	9251 /* sub-frame 1: Interpolation between old and first */
pascal@12756	9252
pascal@12756	9253 LSFinterpolate2a_dec(lp, iLBCdec_inst->lsfdeqold, lsfdeq,
pascal@12756	9254 lsf_weightTbl_30ms[0], length);
pascal@12756	9255 memcpy(syntdenum,lp,lp_length*sizeof(float));
pascal@12756	9256 bwexpand(weightdenum, lp, LPC_CHIRP_WEIGHTDENUM,
pascal@12756	9257 lp_length);
pascal@12756	9258
pascal@12756	9259 /* sub-frames 2 to 6: interpolation between first
pascal@12756	9260 and last LSF */
pascal@12756	9261
pascal@12756	9262 pos = lp_length;
pascal@12756	9263 for (i = 1; i < 6; i++) {
pascal@12756	9264 LSFinterpolate2a_dec(lp, lsfdeq, lsfdeq2,
pascal@12756	9265 lsf_weightTbl_30ms[i], length);
pascal@12756	9266 memcpy(syntdenum + pos,lp,lp_length*sizeof(float));
pascal@12756	9267 bwexpand(weightdenum + pos, lp,
pascal@12756	9268 LPC_CHIRP_WEIGHTDENUM, lp_length);
pascal@12756	9269 pos += lp_length;
pascal@12756	9270 }
pascal@12756	9271 }
pascal@12756	9272 else {
pascal@12756	9273 pos = 0;
pascal@12756	9274 for (i = 0; i < iLBCdec_inst->nsub; i++) {
pascal@12756	9275 LSFinterpolate2a_dec(lp, iLBCdec_inst->lsfdeqold,
pascal@12756	9276 lsfdeq, lsf_weightTbl_20ms[i], length);
pascal@12756	9277 memcpy(syntdenum+pos,lp,lp_length*sizeof(float));
pascal@12756	9278 bwexpand(weightdenum+pos, lp, LPC_CHIRP_WEIGHTDENUM,
pascal@12756	9279 lp_length);
pascal@12756	9280 pos += lp_length;
pascal@12756	9281 }
pascal@12756	9282 }
pascal@12756	9283
pascal@12756	9284 /* update memory */
pascal@12756	9285
pascal@12756	9286 if (iLBCdec_inst->mode==30)
pascal@12756	9287 memcpy(iLBCdec_inst->lsfdeqold, lsfdeq2,
pascal@12756	9288 length*sizeof(float));
pascal@12756	9289 else
pascal@12756	9290 memcpy(iLBCdec_inst->lsfdeqold, lsfdeq,
pascal@12756	9291 length*sizeof(float));
pascal@12756	9292
pascal@12756	9293 }
pascal@12756	9294
pascal@12756	9295
pascal@12756	9296
pascal@12756	9297
pascal@12756	9298 Andersen, et al. Experimental [Page 166]
pascal@12756	9299
pascal@12756	9300 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9301
pascal@12756	9302
pascal@12756	9303 A.37. LPCencode.h
pascal@12756	9304
pascal@12756	9305 /******************************************************************
pascal@12756	9306
pascal@12756	9307 iLBC Speech Coder ANSI-C Source Code
pascal@12756	9308
pascal@12756	9309 LPCencode.h
pascal@12756	9310
pascal@12756	9311 Copyright (C) The Internet Society (2004).
pascal@12756	9312 All Rights Reserved.
pascal@12756	9313
pascal@12756	9314 ******************************************************************/
pascal@12756	9315
pascal@12756	9316 #ifndef __iLBC_LPCENCOD_H
pascal@12756	9317 #define __iLBC_LPCENCOD_H
pascal@12756	9318
pascal@12756	9319 void LPCencode(
pascal@12756	9320 float syntdenum, / (i/o) synthesis filter coefficients
pascal@12756	9321 before/after encoding */
pascal@12756	9322 float weightdenum, / (i/o) weighting denumerator coefficients
pascal@12756	9323 before/after encoding */
pascal@12756	9324 int lsf_index, / (o) lsf quantization index */
pascal@12756	9325 float data, / (i) lsf coefficients to quantize */
pascal@12756	9326 iLBC_Enc_Inst_t *iLBCenc_inst
pascal@12756	9327 /* (i/o) the encoder state structure */
pascal@12756	9328 );
pascal@12756	9329
pascal@12756	9330 #endif
pascal@12756	9331
pascal@12756	9332 A.38. LPCencode.c
pascal@12756	9333
pascal@12756	9334 /******************************************************************
pascal@12756	9335
pascal@12756	9336 iLBC Speech Coder ANSI-C Source Code
pascal@12756	9337
pascal@12756	9338 LPCencode.c
pascal@12756	9339
pascal@12756	9340 Copyright (C) The Internet Society (2004).
pascal@12756	9341 All Rights Reserved.
pascal@12756	9342
pascal@12756	9343 ******************************************************************/
pascal@12756	9344
pascal@12756	9345 #include <string.h>
pascal@12756	9346
pascal@12756	9347 #include "iLBC_define.h"
pascal@12756	9348 #include "helpfun.h"
pascal@12756	9349 #include "lsf.h"
pascal@12756	9350 #include "constants.h"
pascal@12756	9351
pascal@12756	9352
pascal@12756	9353
pascal@12756	9354 Andersen, et al. Experimental [Page 167]
pascal@12756	9355
pascal@12756	9356 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9357
pascal@12756	9358
pascal@12756	9359 /----------------------------------------------------------------
pascal@12756	9360 * lpc analysis (subrutine to LPCencode)
pascal@12756	9361 ---------------------------------------------------------------/
pascal@12756	9362
pascal@12756	9363 void SimpleAnalysis(
pascal@12756	9364 float lsf, / (o) lsf coefficients */
pascal@12756	9365 float data, / (i) new data vector */
pascal@12756	9366 iLBC_Enc_Inst_t *iLBCenc_inst
pascal@12756	9367 /* (i/o) the encoder state structure */
pascal@12756	9368 ){
pascal@12756	9369 int k, is;
pascal@12756	9370 float temp[BLOCKL_MAX], lp[LPC_FILTERORDER + 1];
pascal@12756	9371 float lp2[LPC_FILTERORDER + 1];
pascal@12756	9372 float r[LPC_FILTERORDER + 1];
pascal@12756	9373
pascal@12756	9374 is=LPC_LOOKBACK+BLOCKL_MAX-iLBCenc_inst->blockl;
pascal@12756	9375 memcpy(iLBCenc_inst->lpc_buffer+is,data,
pascal@12756	9376 iLBCenc_inst->blockl*sizeof(float));
pascal@12756	9377
pascal@12756	9378 /* No lookahead, last window is asymmetric */
pascal@12756	9379
pascal@12756	9380 for (k = 0; k < iLBCenc_inst->lpc_n; k++) {
pascal@12756	9381
pascal@12756	9382 is = LPC_LOOKBACK;
pascal@12756	9383
pascal@12756	9384 if (k < (iLBCenc_inst->lpc_n - 1)) {
pascal@12756	9385 window(temp, lpc_winTbl,
pascal@12756	9386 iLBCenc_inst->lpc_buffer, BLOCKL_MAX);
pascal@12756	9387 } else {
pascal@12756	9388 window(temp, lpc_asymwinTbl,
pascal@12756	9389 iLBCenc_inst->lpc_buffer + is, BLOCKL_MAX);
pascal@12756	9390 }
pascal@12756	9391
pascal@12756	9392 autocorr(r, temp, BLOCKL_MAX, LPC_FILTERORDER);
pascal@12756	9393 window(r, r, lpc_lagwinTbl, LPC_FILTERORDER + 1);
pascal@12756	9394
pascal@12756	9395 levdurb(lp, temp, r, LPC_FILTERORDER);
pascal@12756	9396 bwexpand(lp2, lp, LPC_CHIRP_SYNTDENUM, LPC_FILTERORDER+1);
pascal@12756	9397
pascal@12756	9398 a2lsf(lsf + k*LPC_FILTERORDER, lp2);
pascal@12756	9399 }
pascal@12756	9400 is=LPC_LOOKBACK+BLOCKL_MAX-iLBCenc_inst->blockl;
pascal@12756	9401 memmove(iLBCenc_inst->lpc_buffer,
pascal@12756	9402 iLBCenc_inst->lpc_buffer+LPC_LOOKBACK+BLOCKL_MAX-is,
pascal@12756	9403 is*sizeof(float));
pascal@12756	9404 }
pascal@12756	9405
pascal@12756	9406 /----------------------------------------------------------------
pascal@12756	9407
pascal@12756	9408
pascal@12756	9409
pascal@12756	9410 Andersen, et al. Experimental [Page 168]
pascal@12756	9411
pascal@12756	9412 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9413
pascal@12756	9414
pascal@12756	9415 * lsf interpolator and conversion from lsf to a coefficients
pascal@12756	9416 * (subrutine to SimpleInterpolateLSF)
pascal@12756	9417 ---------------------------------------------------------------/
pascal@12756	9418
pascal@12756	9419 void LSFinterpolate2a_enc(
pascal@12756	9420 float a, / (o) lpc coefficients */
pascal@12756	9421 float lsf1,/ (i) first set of lsf coefficients */
pascal@12756	9422 float lsf2,/ (i) second set of lsf coefficients */
pascal@12756	9423 float coef, /* (i) weighting coefficient to use between
pascal@12756	9424 lsf1 and lsf2 */
pascal@12756	9425 long length /* (i) length of coefficient vectors */
pascal@12756	9426 ){
pascal@12756	9427 float lsftmp[LPC_FILTERORDER];
pascal@12756	9428
pascal@12756	9429 interpolate(lsftmp, lsf1, lsf2, coef, length);
pascal@12756	9430 lsf2a(a, lsftmp);
pascal@12756	9431 }
pascal@12756	9432
pascal@12756	9433 /----------------------------------------------------------------
pascal@12756	9434 * lsf interpolator (subrutine to LPCencode)
pascal@12756	9435 ---------------------------------------------------------------/
pascal@12756	9436
pascal@12756	9437 void SimpleInterpolateLSF(
pascal@12756	9438 float syntdenum, / (o) the synthesis filter denominator
pascal@12756	9439 resulting from the quantized
pascal@12756	9440 interpolated lsf */
pascal@12756	9441 float weightdenum, / (o) the weighting filter denominator
pascal@12756	9442 resulting from the unquantized
pascal@12756	9443 interpolated lsf */
pascal@12756	9444 float lsf, / (i) the unquantized lsf coefficients */
pascal@12756	9445 float lsfdeq, / (i) the dequantized lsf coefficients */
pascal@12756	9446 float lsfold, / (i) the unquantized lsf coefficients of
pascal@12756	9447 the previous signal frame */
pascal@12756	9448 float lsfdeqold, / (i) the dequantized lsf coefficients of
pascal@12756	9449 the previous signal frame */
pascal@12756	9450 int length, /* (i) should equate LPC_FILTERORDER */
pascal@12756	9451 iLBC_Enc_Inst_t *iLBCenc_inst
pascal@12756	9452 /* (i/o) the encoder state structure */
pascal@12756	9453 ){
pascal@12756	9454 int i, pos, lp_length;
pascal@12756	9455 float lp[LPC_FILTERORDER + 1], lsf2, lsfdeq2;
pascal@12756	9456
pascal@12756	9457 lsf2 = lsf + length;
pascal@12756	9458 lsfdeq2 = lsfdeq + length;
pascal@12756	9459 lp_length = length + 1;
pascal@12756	9460
pascal@12756	9461 if (iLBCenc_inst->mode==30) {
pascal@12756	9462 /* sub-frame 1: Interpolation between old and first
pascal@12756	9463
pascal@12756	9464
pascal@12756	9465
pascal@12756	9466 Andersen, et al. Experimental [Page 169]
pascal@12756	9467
pascal@12756	9468 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9469
pascal@12756	9470
pascal@12756	9471 set of lsf coefficients */
pascal@12756	9472
pascal@12756	9473 LSFinterpolate2a_enc(lp, lsfdeqold, lsfdeq,
pascal@12756	9474 lsf_weightTbl_30ms[0], length);
pascal@12756	9475 memcpy(syntdenum,lp,lp_length*sizeof(float));
pascal@12756	9476 LSFinterpolate2a_enc(lp, lsfold, lsf,
pascal@12756	9477 lsf_weightTbl_30ms[0], length);
pascal@12756	9478 bwexpand(weightdenum, lp, LPC_CHIRP_WEIGHTDENUM, lp_length);
pascal@12756	9479
pascal@12756	9480 /* sub-frame 2 to 6: Interpolation between first
pascal@12756	9481 and second set of lsf coefficients */
pascal@12756	9482
pascal@12756	9483 pos = lp_length;
pascal@12756	9484 for (i = 1; i < iLBCenc_inst->nsub; i++) {
pascal@12756	9485 LSFinterpolate2a_enc(lp, lsfdeq, lsfdeq2,
pascal@12756	9486 lsf_weightTbl_30ms[i], length);
pascal@12756	9487 memcpy(syntdenum + pos,lp,lp_length*sizeof(float));
pascal@12756	9488
pascal@12756	9489 LSFinterpolate2a_enc(lp, lsf, lsf2,
pascal@12756	9490 lsf_weightTbl_30ms[i], length);
pascal@12756	9491 bwexpand(weightdenum + pos, lp,
pascal@12756	9492 LPC_CHIRP_WEIGHTDENUM, lp_length);
pascal@12756	9493 pos += lp_length;
pascal@12756	9494 }
pascal@12756	9495 }
pascal@12756	9496 else {
pascal@12756	9497 pos = 0;
pascal@12756	9498 for (i = 0; i < iLBCenc_inst->nsub; i++) {
pascal@12756	9499 LSFinterpolate2a_enc(lp, lsfdeqold, lsfdeq,
pascal@12756	9500 lsf_weightTbl_20ms[i], length);
pascal@12756	9501 memcpy(syntdenum+pos,lp,lp_length*sizeof(float));
pascal@12756	9502 LSFinterpolate2a_enc(lp, lsfold, lsf,
pascal@12756	9503 lsf_weightTbl_20ms[i], length);
pascal@12756	9504 bwexpand(weightdenum+pos, lp,
pascal@12756	9505 LPC_CHIRP_WEIGHTDENUM, lp_length);
pascal@12756	9506 pos += lp_length;
pascal@12756	9507 }
pascal@12756	9508 }
pascal@12756	9509
pascal@12756	9510 /* update memory */
pascal@12756	9511
pascal@12756	9512 if (iLBCenc_inst->mode==30) {
pascal@12756	9513 memcpy(lsfold, lsf2, length*sizeof(float));
pascal@12756	9514 memcpy(lsfdeqold, lsfdeq2, length*sizeof(float));
pascal@12756	9515 }
pascal@12756	9516 else {
pascal@12756	9517 memcpy(lsfold, lsf, length*sizeof(float));
pascal@12756	9518 memcpy(lsfdeqold, lsfdeq, length*sizeof(float));
pascal@12756	9519
pascal@12756	9520
pascal@12756	9521
pascal@12756	9522 Andersen, et al. Experimental [Page 170]
pascal@12756	9523
pascal@12756	9524 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9525
pascal@12756	9526
pascal@12756	9527 }
pascal@12756	9528 }
pascal@12756	9529
pascal@12756	9530 /----------------------------------------------------------------
pascal@12756	9531 * lsf quantizer (subrutine to LPCencode)
pascal@12756	9532 ---------------------------------------------------------------/
pascal@12756	9533
pascal@12756	9534 void SimplelsfQ(
pascal@12756	9535 float lsfdeq, / (o) dequantized lsf coefficients
pascal@12756	9536 (dimension FILTERORDER) */
pascal@12756	9537 int index, / (o) quantization index */
pascal@12756	9538 float lsf, / (i) the lsf coefficient vector to be
pascal@12756	9539 quantized (dimension FILTERORDER ) */
pascal@12756	9540 int lpc_n /* (i) number of lsf sets to quantize */
pascal@12756	9541 ){
pascal@12756	9542 /* Quantize first LSF with memoryless split VQ */
pascal@12756	9543 SplitVQ(lsfdeq, index, lsf, lsfCbTbl, LSF_NSPLIT,
pascal@12756	9544 dim_lsfCbTbl, size_lsfCbTbl);
pascal@12756	9545
pascal@12756	9546 if (lpc_n==2) {
pascal@12756	9547 /* Quantize second LSF with memoryless split VQ */
pascal@12756	9548 SplitVQ(lsfdeq + LPC_FILTERORDER, index + LSF_NSPLIT,
pascal@12756	9549 lsf + LPC_FILTERORDER, lsfCbTbl, LSF_NSPLIT,
pascal@12756	9550 dim_lsfCbTbl, size_lsfCbTbl);
pascal@12756	9551 }
pascal@12756	9552 }
pascal@12756	9553
pascal@12756	9554 /----------------------------------------------------------------
pascal@12756	9555 * lpc encoder
pascal@12756	9556 ---------------------------------------------------------------/
pascal@12756	9557
pascal@12756	9558 void LPCencode(
pascal@12756	9559 float syntdenum, / (i/o) synthesis filter coefficients
pascal@12756	9560 before/after encoding */
pascal@12756	9561 float weightdenum, / (i/o) weighting denumerator
pascal@12756	9562 coefficients before/after
pascal@12756	9563 encoding */
pascal@12756	9564 int lsf_index, / (o) lsf quantization index */
pascal@12756	9565 float data, / (i) lsf coefficients to quantize */
pascal@12756	9566 iLBC_Enc_Inst_t *iLBCenc_inst
pascal@12756	9567 /* (i/o) the encoder state structure */
pascal@12756	9568 ){
pascal@12756	9569 float lsf[LPC_FILTERORDER * LPC_N_MAX];
pascal@12756	9570 float lsfdeq[LPC_FILTERORDER * LPC_N_MAX];
pascal@12756	9571 int change=0;
pascal@12756	9572
pascal@12756	9573 SimpleAnalysis(lsf, data, iLBCenc_inst);
pascal@12756	9574 SimplelsfQ(lsfdeq, lsf_index, lsf, iLBCenc_inst->lpc_n);
pascal@12756	9575
pascal@12756	9576
pascal@12756	9577
pascal@12756	9578 Andersen, et al. Experimental [Page 171]
pascal@12756	9579
pascal@12756	9580 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9581
pascal@12756	9582
pascal@12756	9583 change=LSF_check(lsfdeq, LPC_FILTERORDER, iLBCenc_inst->lpc_n);
pascal@12756	9584 SimpleInterpolateLSF(syntdenum, weightdenum,
pascal@12756	9585 lsf, lsfdeq, iLBCenc_inst->lsfold,
pascal@12756	9586 iLBCenc_inst->lsfdeqold, LPC_FILTERORDER, iLBCenc_inst);
pascal@12756	9587 }
pascal@12756	9588
pascal@12756	9589 A.39. lsf.h
pascal@12756	9590
pascal@12756	9591 /******************************************************************
pascal@12756	9592
pascal@12756	9593 iLBC Speech Coder ANSI-C Source Code
pascal@12756	9594
pascal@12756	9595 lsf.h
pascal@12756	9596
pascal@12756	9597 Copyright (C) The Internet Society (2004).
pascal@12756	9598 All Rights Reserved.
pascal@12756	9599
pascal@12756	9600 ******************************************************************/
pascal@12756	9601
pascal@12756	9602 #ifndef __iLBC_LSF_H
pascal@12756	9603 #define __iLBC_LSF_H
pascal@12756	9604
pascal@12756	9605 void a2lsf(
pascal@12756	9606 float freq,/ (o) lsf coefficients */
pascal@12756	9607 float a / (i) lpc coefficients */
pascal@12756	9608 );
pascal@12756	9609
pascal@12756	9610 void lsf2a(
pascal@12756	9611 float a_coef, / (o) lpc coefficients */
pascal@12756	9612 float freq / (i) lsf coefficients */
pascal@12756	9613 );
pascal@12756	9614
pascal@12756	9615 #endif
pascal@12756	9616
pascal@12756	9617 A.40. lsf.c
pascal@12756	9618
pascal@12756	9619 /******************************************************************
pascal@12756	9620
pascal@12756	9621 iLBC Speech Coder ANSI-C Source Code
pascal@12756	9622
pascal@12756	9623 lsf.c
pascal@12756	9624
pascal@12756	9625 Copyright (C) The Internet Society (2004).
pascal@12756	9626 All Rights Reserved.
pascal@12756	9627
pascal@12756	9628 ******************************************************************/
pascal@12756	9629
pascal@12756	9630 #include <string.h>
pascal@12756	9631
pascal@12756	9632
pascal@12756	9633
pascal@12756	9634 Andersen, et al. Experimental [Page 172]
pascal@12756	9635
pascal@12756	9636 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9637
pascal@12756	9638
pascal@12756	9639 #include <math.h>
pascal@12756	9640
pascal@12756	9641 #include "iLBC_define.h"
pascal@12756	9642
pascal@12756	9643 /----------------------------------------------------------------
pascal@12756	9644 * conversion from lpc coefficients to lsf coefficients
pascal@12756	9645 ---------------------------------------------------------------/
pascal@12756	9646
pascal@12756	9647 void a2lsf(
pascal@12756	9648 float freq,/ (o) lsf coefficients */
pascal@12756	9649 float a / (i) lpc coefficients */
pascal@12756	9650 ){
pascal@12756	9651 float steps[LSF_NUMBER_OF_STEPS] =
pascal@12756	9652 {(float)0.00635, (float)0.003175, (float)0.0015875,
pascal@12756	9653 (float)0.00079375};
pascal@12756	9654 float step;
pascal@12756	9655 int step_idx;
pascal@12756	9656 int lsp_index;
pascal@12756	9657 float p[LPC_HALFORDER];
pascal@12756	9658 float q[LPC_HALFORDER];
pascal@12756	9659 float p_pre[LPC_HALFORDER];
pascal@12756	9660 float q_pre[LPC_HALFORDER];
pascal@12756	9661 float old_p, old_q, *old;
pascal@12756	9662 float *pq_coef;
pascal@12756	9663 float omega, old_omega;
pascal@12756	9664 int i;
pascal@12756	9665 float hlp, hlp1, hlp2, hlp3, hlp4, hlp5;
pascal@12756	9666
pascal@12756	9667 for (i=0; i<LPC_HALFORDER; i++) {
pascal@12756	9668 p[i] = (float)-1.0 * (a[i + 1] + a[LPC_FILTERORDER - i]);
pascal@12756	9669 q[i] = a[LPC_FILTERORDER - i] - a[i + 1];
pascal@12756	9670 }
pascal@12756	9671
pascal@12756	9672 p_pre[0] = (float)-1.0 - p[0];
pascal@12756	9673 p_pre[1] = - p_pre[0] - p[1];
pascal@12756	9674 p_pre[2] = - p_pre[1] - p[2];
pascal@12756	9675 p_pre[3] = - p_pre[2] - p[3];
pascal@12756	9676 p_pre[4] = - p_pre[3] - p[4];
pascal@12756	9677 p_pre[4] = p_pre[4] / 2;
pascal@12756	9678
pascal@12756	9679 q_pre[0] = (float)1.0 - q[0];
pascal@12756	9680 q_pre[1] = q_pre[0] - q[1];
pascal@12756	9681 q_pre[2] = q_pre[1] - q[2];
pascal@12756	9682 q_pre[3] = q_pre[2] - q[3];
pascal@12756	9683 q_pre[4] = q_pre[3] - q[4];
pascal@12756	9684 q_pre[4] = q_pre[4] / 2;
pascal@12756	9685
pascal@12756	9686 omega = 0.0;
pascal@12756	9687
pascal@12756	9688
pascal@12756	9689
pascal@12756	9690 Andersen, et al. Experimental [Page 173]
pascal@12756	9691
pascal@12756	9692 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9693
pascal@12756	9694
pascal@12756	9695 old_omega = 0.0;
pascal@12756	9696
pascal@12756	9697 old_p = FLOAT_MAX;
pascal@12756	9698 old_q = FLOAT_MAX;
pascal@12756	9699
pascal@12756	9700 /* Here we loop through lsp_index to find all the
pascal@12756	9701 LPC_FILTERORDER roots for omega. */
pascal@12756	9702
pascal@12756	9703 for (lsp_index = 0; lsp_index<LPC_FILTERORDER; lsp_index++) {
pascal@12756	9704
pascal@12756	9705 /* Depending on lsp_index being even or odd, we
pascal@12756	9706 alternatively solve the roots for the two LSP equations. */
pascal@12756	9707
pascal@12756	9708
pascal@12756	9709 if ((lsp_index & 0x1) == 0) {
pascal@12756	9710 pq_coef = p_pre;
pascal@12756	9711 old = &old_p;
pascal@12756	9712 } else {
pascal@12756	9713 pq_coef = q_pre;
pascal@12756	9714 old = &old_q;
pascal@12756	9715 }
pascal@12756	9716
pascal@12756	9717 /* Start with low resolution grid */
pascal@12756	9718
pascal@12756	9719 for (step_idx = 0, step = steps[step_idx];
pascal@12756	9720 step_idx < LSF_NUMBER_OF_STEPS;){
pascal@12756	9721
pascal@12756	9722 /* cos(10piw) + pq(0)cos(8piw) + pq(1)cos(6piw) +
pascal@12756	9723 pq(2)cos(4piw) + pq(3)cod(2piw) + pq(4) */
pascal@12756	9724
pascal@12756	9725 hlp = (float)cos(omega * TWO_PI);
pascal@12756	9726 hlp1 = (float)2.0 * hlp + pq_coef[0];
pascal@12756	9727 hlp2 = (float)2.0 * hlp * hlp1 - (float)1.0 +
pascal@12756	9728 pq_coef[1];
pascal@12756	9729 hlp3 = (float)2.0 * hlp * hlp2 - hlp1 + pq_coef[2];
pascal@12756	9730 hlp4 = (float)2.0 * hlp * hlp3 - hlp2 + pq_coef[3];
pascal@12756	9731 hlp5 = hlp * hlp4 - hlp3 + pq_coef[4];
pascal@12756	9732
pascal@12756	9733
pascal@12756	9734 if (((hlp5 * (*old)) <= 0.0) \|\| (omega >= 0.5)){
pascal@12756	9735
pascal@12756	9736 if (step_idx == (LSF_NUMBER_OF_STEPS - 1)){
pascal@12756	9737
pascal@12756	9738 if (fabs(hlp5) >= fabs(*old)) {
pascal@12756	9739 freq[lsp_index] = omega - step;
pascal@12756	9740 } else {
pascal@12756	9741 freq[lsp_index] = omega;
pascal@12756	9742 }
pascal@12756	9743
pascal@12756	9744
pascal@12756	9745
pascal@12756	9746 Andersen, et al. Experimental [Page 174]
pascal@12756	9747
pascal@12756	9748 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9749
pascal@12756	9750
pascal@12756	9751
pascal@12756	9752
pascal@12756	9753 if ((*old) >= 0.0){
pascal@12756	9754 old = (float)-1.0 FLOAT_MAX;
pascal@12756	9755 } else {
pascal@12756	9756 *old = FLOAT_MAX;
pascal@12756	9757 }
pascal@12756	9758
pascal@12756	9759 omega = old_omega;
pascal@12756	9760 step_idx = 0;
pascal@12756	9761
pascal@12756	9762 step_idx = LSF_NUMBER_OF_STEPS;
pascal@12756	9763 } else {
pascal@12756	9764
pascal@12756	9765 if (step_idx == 0) {
pascal@12756	9766 old_omega = omega;
pascal@12756	9767 }
pascal@12756	9768
pascal@12756	9769 step_idx++;
pascal@12756	9770 omega -= steps[step_idx];
pascal@12756	9771
pascal@12756	9772 /* Go back one grid step */
pascal@12756	9773
pascal@12756	9774 step = steps[step_idx];
pascal@12756	9775 }
pascal@12756	9776 } else {
pascal@12756	9777
pascal@12756	9778 /* increment omega until they are of different sign,
pascal@12756	9779 and we know there is at least one root between omega
pascal@12756	9780 and old_omega */
pascal@12756	9781 *old = hlp5;
pascal@12756	9782 omega += step;
pascal@12756	9783 }
pascal@12756	9784 }
pascal@12756	9785 }
pascal@12756	9786
pascal@12756	9787 for (i = 0; i<LPC_FILTERORDER; i++) {
pascal@12756	9788 freq[i] = freq[i] * TWO_PI;
pascal@12756	9789 }
pascal@12756	9790 }
pascal@12756	9791
pascal@12756	9792 /----------------------------------------------------------------
pascal@12756	9793 * conversion from lsf coefficients to lpc coefficients
pascal@12756	9794 ---------------------------------------------------------------/
pascal@12756	9795
pascal@12756	9796 void lsf2a(
pascal@12756	9797 float a_coef, / (o) lpc coefficients */
pascal@12756	9798 float freq / (i) lsf coefficients */
pascal@12756	9799
pascal@12756	9800
pascal@12756	9801
pascal@12756	9802 Andersen, et al. Experimental [Page 175]
pascal@12756	9803
pascal@12756	9804 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9805
pascal@12756	9806
pascal@12756	9807 ){
pascal@12756	9808 int i, j;
pascal@12756	9809 float hlp;
pascal@12756	9810 float p[LPC_HALFORDER], q[LPC_HALFORDER];
pascal@12756	9811 float a[LPC_HALFORDER + 1], a1[LPC_HALFORDER],
pascal@12756	9812 a2[LPC_HALFORDER];
pascal@12756	9813 float b[LPC_HALFORDER + 1], b1[LPC_HALFORDER],
pascal@12756	9814 b2[LPC_HALFORDER];
pascal@12756	9815
pascal@12756	9816 for (i=0; i<LPC_FILTERORDER; i++) {
pascal@12756	9817 freq[i] = freq[i] * PI2;
pascal@12756	9818 }
pascal@12756	9819
pascal@12756	9820 /* Check input for ill-conditioned cases. This part is not
pascal@12756	9821 found in the TIA standard. It involves the following 2 IF
pascal@12756	9822 blocks. If "freq" is judged ill-conditioned, then we first
pascal@12756	9823 modify freq[0] and freq[LPC_HALFORDER-1] (normally
pascal@12756	9824 LPC_HALFORDER = 10 for LPC applications), then we adjust
pascal@12756	9825 the other "freq" values slightly */
pascal@12756	9826
pascal@12756	9827
pascal@12756	9828 if ((freq[0] <= 0.0) \|\| (freq[LPC_FILTERORDER - 1] >= 0.5)){
pascal@12756	9829
pascal@12756	9830
pascal@12756	9831 if (freq[0] <= 0.0) {
pascal@12756	9832 freq[0] = (float)0.022;
pascal@12756	9833 }
pascal@12756	9834
pascal@12756	9835
pascal@12756	9836 if (freq[LPC_FILTERORDER - 1] >= 0.5) {
pascal@12756	9837 freq[LPC_FILTERORDER - 1] = (float)0.499;
pascal@12756	9838 }
pascal@12756	9839
pascal@12756	9840 hlp = (freq[LPC_FILTERORDER - 1] - freq[0]) /
pascal@12756	9841 (float) (LPC_FILTERORDER - 1);
pascal@12756	9842
pascal@12756	9843 for (i=1; i<LPC_FILTERORDER; i++) {
pascal@12756	9844 freq[i] = freq[i - 1] + hlp;
pascal@12756	9845 }
pascal@12756	9846 }
pascal@12756	9847
pascal@12756	9848 memset(a1, 0, LPC_HALFORDER*sizeof(float));
pascal@12756	9849 memset(a2, 0, LPC_HALFORDER*sizeof(float));
pascal@12756	9850 memset(b1, 0, LPC_HALFORDER*sizeof(float));
pascal@12756	9851 memset(b2, 0, LPC_HALFORDER*sizeof(float));
pascal@12756	9852 memset(a, 0, (LPC_HALFORDER+1)*sizeof(float));
pascal@12756	9853 memset(b, 0, (LPC_HALFORDER+1)*sizeof(float));
pascal@12756	9854
pascal@12756	9855
pascal@12756	9856
pascal@12756	9857
pascal@12756	9858 Andersen, et al. Experimental [Page 176]
pascal@12756	9859
pascal@12756	9860 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9861
pascal@12756	9862
pascal@12756	9863 /* p[i] and q[i] compute cos(2piomega_{2j}) and
pascal@12756	9864 cos(2piomega_{2j-1} in eqs. 4.2.2.2-1 and 4.2.2.2-2.
pascal@12756	9865 Note that for this code p[i] specifies the coefficients
pascal@12756	9866 used in .Q_A(z) while q[i] specifies the coefficients used
pascal@12756	9867 in .P_A(z) */
pascal@12756	9868
pascal@12756	9869 for (i=0; i<LPC_HALFORDER; i++) {
pascal@12756	9870 p[i] = (float)cos(TWO_PI * freq[2 * i]);
pascal@12756	9871 q[i] = (float)cos(TWO_PI * freq[2 * i + 1]);
pascal@12756	9872 }
pascal@12756	9873
pascal@12756	9874 a[0] = 0.25;
pascal@12756	9875 b[0] = 0.25;
pascal@12756	9876
pascal@12756	9877 for (i= 0; i<LPC_HALFORDER; i++) {
pascal@12756	9878 a[i + 1] = a[i] - 2 * p[i] * a1[i] + a2[i];
pascal@12756	9879 b[i + 1] = b[i] - 2 * q[i] * b1[i] + b2[i];
pascal@12756	9880 a2[i] = a1[i];
pascal@12756	9881 a1[i] = a[i];
pascal@12756	9882 b2[i] = b1[i];
pascal@12756	9883 b1[i] = b[i];
pascal@12756	9884 }
pascal@12756	9885
pascal@12756	9886 for (j=0; j<LPC_FILTERORDER; j++) {
pascal@12756	9887
pascal@12756	9888 if (j == 0) {
pascal@12756	9889 a[0] = 0.25;
pascal@12756	9890 b[0] = -0.25;
pascal@12756	9891 } else {
pascal@12756	9892 a[0] = b[0] = 0.0;
pascal@12756	9893 }
pascal@12756	9894
pascal@12756	9895 for (i=0; i<LPC_HALFORDER; i++) {
pascal@12756	9896 a[i + 1] = a[i] - 2 * p[i] * a1[i] + a2[i];
pascal@12756	9897 b[i + 1] = b[i] - 2 * q[i] * b1[i] + b2[i];
pascal@12756	9898 a2[i] = a1[i];
pascal@12756	9899 a1[i] = a[i];
pascal@12756	9900 b2[i] = b1[i];
pascal@12756	9901 b1[i] = b[i];
pascal@12756	9902 }
pascal@12756	9903
pascal@12756	9904 a_coef[j + 1] = 2 * (a[LPC_HALFORDER] + b[LPC_HALFORDER]);
pascal@12756	9905 }
pascal@12756	9906
pascal@12756	9907 a_coef[0] = 1.0;
pascal@12756	9908 }
pascal@12756	9909
pascal@12756	9910
pascal@12756	9911
pascal@12756	9912
pascal@12756	9913
pascal@12756	9914 Andersen, et al. Experimental [Page 177]
pascal@12756	9915
pascal@12756	9916 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9917
pascal@12756	9918
pascal@12756	9919 A.41. packing.h
pascal@12756	9920
pascal@12756	9921 /******************************************************************
pascal@12756	9922
pascal@12756	9923 iLBC Speech Coder ANSI-C Source Code
pascal@12756	9924
pascal@12756	9925 packing.h
pascal@12756	9926
pascal@12756	9927 Copyright (C) The Internet Society (2004).
pascal@12756	9928 All Rights Reserved.
pascal@12756	9929
pascal@12756	9930 ******************************************************************/
pascal@12756	9931
pascal@12756	9932 #ifndef __PACKING_H
pascal@12756	9933 #define __PACKING_H
pascal@12756	9934
pascal@12756	9935 void packsplit(
pascal@12756	9936 int index, / (i) the value to split */
pascal@12756	9937 int firstpart, / (o) the value specified by most
pascal@12756	9938 significant bits */
pascal@12756	9939 int rest, / (o) the value specified by least
pascal@12756	9940 significant bits */
pascal@12756	9941 int bitno_firstpart, /* (i) number of bits in most
pascal@12756	9942 significant part */
pascal@12756	9943 int bitno_total /* (i) number of bits in full range
pascal@12756	9944 of value */
pascal@12756	9945 );
pascal@12756	9946
pascal@12756	9947 void packcombine(
pascal@12756	9948 int index, / (i/o) the msb value in the
pascal@12756	9949 combined value out */
pascal@12756	9950 int rest, /* (i) the lsb value */
pascal@12756	9951 int bitno_rest /* (i) the number of bits in the
pascal@12756	9952 lsb part */
pascal@12756	9953 );
pascal@12756	9954
pascal@12756	9955 void dopack(
pascal@12756	9956 unsigned char *bitstream, / (i/o) on entrance pointer to
pascal@12756	9957 place in bitstream to pack
pascal@12756	9958 new data, on exit pointer
pascal@12756	9959 to place in bitstream to
pascal@12756	9960 pack future data */
pascal@12756	9961 int index, /* (i) the value to pack */
pascal@12756	9962 int bitno, /* (i) the number of bits that the
pascal@12756	9963 value will fit within */
pascal@12756	9964 int pos / (i/o) write position in the
pascal@12756	9965 current byte */
pascal@12756	9966 );
pascal@12756	9967
pascal@12756	9968
pascal@12756	9969
pascal@12756	9970 Andersen, et al. Experimental [Page 178]
pascal@12756	9971
pascal@12756	9972 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	9973
pascal@12756	9974
pascal@12756	9975 void unpack(
pascal@12756	9976 unsigned char *bitstream, / (i/o) on entrance pointer to
pascal@12756	9977 place in bitstream to
pascal@12756	9978 unpack new data from, on
pascal@12756	9979 exit pointer to place in
pascal@12756	9980 bitstream to unpack future
pascal@12756	9981 data from */
pascal@12756	9982 int index, / (o) resulting value */
pascal@12756	9983 int bitno, /* (i) number of bits used to
pascal@12756	9984 represent the value */
pascal@12756	9985 int pos / (i/o) read position in the
pascal@12756	9986 current byte */
pascal@12756	9987 );
pascal@12756	9988
pascal@12756	9989 #endif
pascal@12756	9990
pascal@12756	9991 A.42. packing.c
pascal@12756	9992
pascal@12756	9993 /******************************************************************
pascal@12756	9994
pascal@12756	9995 iLBC Speech Coder ANSI-C Source Code
pascal@12756	9996
pascal@12756	9997 packing.c
pascal@12756	9998
pascal@12756	9999 Copyright (C) The Internet Society (2004).
pascal@12756	10000 All Rights Reserved.
pascal@12756	10001
pascal@12756	10002 ******************************************************************/
pascal@12756	10003
pascal@12756	10004 #include <math.h>
pascal@12756	10005 #include <stdlib.h>
pascal@12756	10006
pascal@12756	10007 #include "iLBC_define.h"
pascal@12756	10008 #include "constants.h"
pascal@12756	10009 #include "helpfun.h"
pascal@12756	10010 #include "string.h"
pascal@12756	10011
pascal@12756	10012 /----------------------------------------------------------------
pascal@12756	10013 * splitting an integer into first most significant bits and
pascal@12756	10014 * remaining least significant bits
pascal@12756	10015 ---------------------------------------------------------------/
pascal@12756	10016
pascal@12756	10017 void packsplit(
pascal@12756	10018 int index, / (i) the value to split */
pascal@12756	10019 int firstpart, / (o) the value specified by most
pascal@12756	10020 significant bits */
pascal@12756	10021 int rest, / (o) the value specified by least
pascal@12756	10022 significant bits */
pascal@12756	10023
pascal@12756	10024
pascal@12756	10025
pascal@12756	10026 Andersen, et al. Experimental [Page 179]
pascal@12756	10027
pascal@12756	10028 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10029
pascal@12756	10030
pascal@12756	10031 int bitno_firstpart, /* (i) number of bits in most
pascal@12756	10032 significant part */
pascal@12756	10033 int bitno_total /* (i) number of bits in full range
pascal@12756	10034 of value */
pascal@12756	10035 ){
pascal@12756	10036 int bitno_rest = bitno_total-bitno_firstpart;
pascal@12756	10037
pascal@12756	10038 firstpart = index>>(bitno_rest);
pascal@12756	10039 rest = index-(*firstpart<<(bitno_rest));
pascal@12756	10040 }
pascal@12756	10041
pascal@12756	10042 /----------------------------------------------------------------
pascal@12756	10043 * combining a value corresponding to msb's with a value
pascal@12756	10044 * corresponding to lsb's
pascal@12756	10045 ---------------------------------------------------------------/
pascal@12756	10046
pascal@12756	10047 void packcombine(
pascal@12756	10048 int index, / (i/o) the msb value in the
pascal@12756	10049 combined value out */
pascal@12756	10050 int rest, /* (i) the lsb value */
pascal@12756	10051 int bitno_rest /* (i) the number of bits in the
pascal@12756	10052 lsb part */
pascal@12756	10053 ){
pascal@12756	10054 index = index<<bitno_rest;
pascal@12756	10055 *index += rest;
pascal@12756	10056 }
pascal@12756	10057
pascal@12756	10058 /----------------------------------------------------------------
pascal@12756	10059 * packing of bits into bitstream, i.e., vector of bytes
pascal@12756	10060 ---------------------------------------------------------------/
pascal@12756	10061
pascal@12756	10062 void dopack(
pascal@12756	10063 unsigned char *bitstream, / (i/o) on entrance pointer to
pascal@12756	10064 place in bitstream to pack
pascal@12756	10065 new data, on exit pointer
pascal@12756	10066 to place in bitstream to
pascal@12756	10067 pack future data */
pascal@12756	10068 int index, /* (i) the value to pack */
pascal@12756	10069 int bitno, /* (i) the number of bits that the
pascal@12756	10070 value will fit within */
pascal@12756	10071 int pos / (i/o) write position in the
pascal@12756	10072 current byte */
pascal@12756	10073 ){
pascal@12756	10074 int posLeft;
pascal@12756	10075
pascal@12756	10076 /* Clear the bits before starting in a new byte */
pascal@12756	10077
pascal@12756	10078 if ((*pos)==0) {
pascal@12756	10079
pascal@12756	10080
pascal@12756	10081
pascal@12756	10082 Andersen, et al. Experimental [Page 180]
pascal@12756	10083
pascal@12756	10084 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10085
pascal@12756	10086
pascal@12756	10087 **bitstream=0;
pascal@12756	10088 }
pascal@12756	10089
pascal@12756	10090 while (bitno>0) {
pascal@12756	10091
pascal@12756	10092 /* Jump to the next byte if end of this byte is reached*/
pascal@12756	10093
pascal@12756	10094 if (*pos==8) {
pascal@12756	10095 *pos=0;
pascal@12756	10096 (*bitstream)++;
pascal@12756	10097 **bitstream=0;
pascal@12756	10098 }
pascal@12756	10099
pascal@12756	10100 posLeft=8-(*pos);
pascal@12756	10101
pascal@12756	10102 /* Insert index into the bitstream */
pascal@12756	10103
pascal@12756	10104 if (bitno <= posLeft) {
pascal@12756	10105 **bitstream \|= (unsigned char)(index<<(posLeft-bitno));
pascal@12756	10106 *pos+=bitno;
pascal@12756	10107 bitno=0;
pascal@12756	10108 } else {
pascal@12756	10109 **bitstream \|= (unsigned char)(index>>(bitno-posLeft));
pascal@12756	10110
pascal@12756	10111 *pos=8;
pascal@12756	10112 index-=((index>>(bitno-posLeft))<<(bitno-posLeft));
pascal@12756	10113
pascal@12756	10114 bitno-=posLeft;
pascal@12756	10115 }
pascal@12756	10116 }
pascal@12756	10117 }
pascal@12756	10118
pascal@12756	10119 /----------------------------------------------------------------
pascal@12756	10120 * unpacking of bits from bitstream, i.e., vector of bytes
pascal@12756	10121 ---------------------------------------------------------------/
pascal@12756	10122
pascal@12756	10123 void unpack(
pascal@12756	10124 unsigned char *bitstream, / (i/o) on entrance pointer to
pascal@12756	10125 place in bitstream to
pascal@12756	10126 unpack new data from, on
pascal@12756	10127 exit pointer to place in
pascal@12756	10128 bitstream to unpack future
pascal@12756	10129 data from */
pascal@12756	10130 int index, / (o) resulting value */
pascal@12756	10131 int bitno, /* (i) number of bits used to
pascal@12756	10132 represent the value */
pascal@12756	10133 int pos / (i/o) read position in the
pascal@12756	10134 current byte */
pascal@12756	10135
pascal@12756	10136
pascal@12756	10137
pascal@12756	10138 Andersen, et al. Experimental [Page 181]
pascal@12756	10139
pascal@12756	10140 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10141
pascal@12756	10142
pascal@12756	10143 ){
pascal@12756	10144 int BitsLeft;
pascal@12756	10145
pascal@12756	10146 *index=0;
pascal@12756	10147
pascal@12756	10148 while (bitno>0) {
pascal@12756	10149
pascal@12756	10150 /* move forward in bitstream when the end of the
pascal@12756	10151 byte is reached */
pascal@12756	10152
pascal@12756	10153 if (*pos==8) {
pascal@12756	10154 *pos=0;
pascal@12756	10155 (*bitstream)++;
pascal@12756	10156 }
pascal@12756	10157
pascal@12756	10158 BitsLeft=8-(*pos);
pascal@12756	10159
pascal@12756	10160 /* Extract bits to index */
pascal@12756	10161
pascal@12756	10162 if (BitsLeft>=bitno) {
pascal@12756	10163 index+=((((bitstream)<<(pos)) & 0xFF)>>(8-bitno));
pascal@12756	10164
pascal@12756	10165 *pos+=bitno;
pascal@12756	10166 bitno=0;
pascal@12756	10167 } else {
pascal@12756	10168
pascal@12756	10169 if ((8-bitno)>0) {
pascal@12756	10170 index+=((((bitstream)<<(pos)) & 0xFF)>>
pascal@12756	10171 (8-bitno));
pascal@12756	10172 *pos=8;
pascal@12756	10173 } else {
pascal@12756	10174 index+=(((int)(((bitstream)<<(pos)) & 0xFF))<<
pascal@12756	10175 (bitno-8));
pascal@12756	10176 *pos=8;
pascal@12756	10177 }
pascal@12756	10178 bitno-=BitsLeft;
pascal@12756	10179 }
pascal@12756	10180 }
pascal@12756	10181 }
pascal@12756	10182
pascal@12756	10183 A.43. StateConstructW.h
pascal@12756	10184
pascal@12756	10185 /******************************************************************
pascal@12756	10186
pascal@12756	10187 iLBC Speech Coder ANSI-C Source Code
pascal@12756	10188
pascal@12756	10189 StateConstructW.h
pascal@12756	10190
pascal@12756	10191
pascal@12756	10192
pascal@12756	10193
pascal@12756	10194 Andersen, et al. Experimental [Page 182]
pascal@12756	10195
pascal@12756	10196 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10197
pascal@12756	10198
pascal@12756	10199 Copyright (C) The Internet Society (2004).
pascal@12756	10200 All Rights Reserved.
pascal@12756	10201
pascal@12756	10202 ******************************************************************/
pascal@12756	10203
pascal@12756	10204 #ifndef __iLBC_STATECONSTRUCTW_H
pascal@12756	10205 #define __iLBC_STATECONSTRUCTW_H
pascal@12756	10206
pascal@12756	10207 void StateConstructW(
pascal@12756	10208 int idxForMax, /* (i) 6-bit index for the quantization of
pascal@12756	10209 max amplitude */
pascal@12756	10210 int idxVec, / (i) vector of quantization indexes */
pascal@12756	10211 float syntDenum, / (i) synthesis filter denumerator */
pascal@12756	10212 float out, / (o) the decoded state vector */
pascal@12756	10213 int len /* (i) length of a state vector */
pascal@12756	10214 );
pascal@12756	10215
pascal@12756	10216 #endif
pascal@12756	10217
pascal@12756	10218 A.44. StateConstructW.c
pascal@12756	10219
pascal@12756	10220 /******************************************************************
pascal@12756	10221
pascal@12756	10222 iLBC Speech Coder ANSI-C Source Code
pascal@12756	10223
pascal@12756	10224 StateConstructW.c
pascal@12756	10225
pascal@12756	10226 Copyright (C) The Internet Society (2004).
pascal@12756	10227 All Rights Reserved.
pascal@12756	10228
pascal@12756	10229 ******************************************************************/
pascal@12756	10230
pascal@12756	10231 #include <math.h>
pascal@12756	10232 #include <string.h>
pascal@12756	10233
pascal@12756	10234 #include "iLBC_define.h"
pascal@12756	10235 #include "constants.h"
pascal@12756	10236 #include "filter.h"
pascal@12756	10237
pascal@12756	10238 /----------------------------------------------------------------
pascal@12756	10239 * decoding of the start state
pascal@12756	10240 ---------------------------------------------------------------/
pascal@12756	10241
pascal@12756	10242 void StateConstructW(
pascal@12756	10243 int idxForMax, /* (i) 6-bit index for the quantization of
pascal@12756	10244 max amplitude */
pascal@12756	10245 int idxVec, / (i) vector of quantization indexes */
pascal@12756	10246 float syntDenum, / (i) synthesis filter denumerator */
pascal@12756	10247
pascal@12756	10248
pascal@12756	10249
pascal@12756	10250 Andersen, et al. Experimental [Page 183]
pascal@12756	10251
pascal@12756	10252 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10253
pascal@12756	10254
pascal@12756	10255 float out, / (o) the decoded state vector */
pascal@12756	10256 int len /* (i) length of a state vector */
pascal@12756	10257 ){
pascal@12756	10258 float maxVal, tmpbuf[LPC_FILTERORDER+2STATE_LEN], tmp,
pascal@12756	10259 numerator[LPC_FILTERORDER+1];
pascal@12756	10260 float foutbuf[LPC_FILTERORDER+2STATE_LEN], fout;
pascal@12756	10261 int k,tmpi;
pascal@12756	10262
pascal@12756	10263 /* decoding of the maximum value */
pascal@12756	10264
pascal@12756	10265 maxVal = state_frgqTbl[idxForMax];
pascal@12756	10266 maxVal = (float)pow(10,maxVal)/(float)4.5;
pascal@12756	10267
pascal@12756	10268 /* initialization of buffers and coefficients */
pascal@12756	10269
pascal@12756	10270 memset(tmpbuf, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	10271 memset(foutbuf, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	10272 for (k=0; k<LPC_FILTERORDER; k++) {
pascal@12756	10273 numerator[k]=syntDenum[LPC_FILTERORDER-k];
pascal@12756	10274 }
pascal@12756	10275 numerator[LPC_FILTERORDER]=syntDenum[0];
pascal@12756	10276 tmp = &tmpbuf[LPC_FILTERORDER];
pascal@12756	10277 fout = &foutbuf[LPC_FILTERORDER];
pascal@12756	10278
pascal@12756	10279 /* decoding of the sample values */
pascal@12756	10280
pascal@12756	10281 for (k=0; k<len; k++) {
pascal@12756	10282 tmpi = len-1-k;
pascal@12756	10283 /* maxVal = 1/scal */
pascal@12756	10284 tmp[k] = maxVal*state_sq3Tbl[idxVec[tmpi]];
pascal@12756	10285 }
pascal@12756	10286
pascal@12756	10287 /* circular convolution with all-pass filter */
pascal@12756	10288
pascal@12756	10289 memset(tmp+len, 0, len*sizeof(float));
pascal@12756	10290 ZeroPoleFilter(tmp, numerator, syntDenum, 2*len,
pascal@12756	10291 LPC_FILTERORDER, fout);
pascal@12756	10292 for (k=0;k<len;k++) {
pascal@12756	10293 out[k] = fout[len-1-k]+fout[2*len-1-k];
pascal@12756	10294 }
pascal@12756	10295 }
pascal@12756	10296
pascal@12756	10297
pascal@12756	10298
pascal@12756	10299
pascal@12756	10300
pascal@12756	10301
pascal@12756	10302
pascal@12756	10303
pascal@12756	10304
pascal@12756	10305
pascal@12756	10306 Andersen, et al. Experimental [Page 184]
pascal@12756	10307
pascal@12756	10308 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10309
pascal@12756	10310
pascal@12756	10311 A.45. StateSearchW.h
pascal@12756	10312
pascal@12756	10313 /******************************************************************
pascal@12756	10314
pascal@12756	10315 iLBC Speech Coder ANSI-C Source Code
pascal@12756	10316
pascal@12756	10317 StateSearchW.h
pascal@12756	10318
pascal@12756	10319 Copyright (C) The Internet Society (2004).
pascal@12756	10320 All Rights Reserved.
pascal@12756	10321
pascal@12756	10322 ******************************************************************/
pascal@12756	10323
pascal@12756	10324 #ifndef __iLBC_STATESEARCHW_H
pascal@12756	10325 #define __iLBC_STATESEARCHW_H
pascal@12756	10326
pascal@12756	10327 void AbsQuantW(
pascal@12756	10328 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	10329 /* (i) Encoder instance */
pascal@12756	10330 float in, / (i) vector to encode */
pascal@12756	10331 float syntDenum, / (i) denominator of synthesis filter */
pascal@12756	10332 float weightDenum, / (i) denominator of weighting filter */
pascal@12756	10333 int out, / (o) vector of quantizer indexes */
pascal@12756	10334 int len, /* (i) length of vector to encode and
pascal@12756	10335 vector of quantizer indexes */
pascal@12756	10336 int state_first /* (i) position of start state in the
pascal@12756	10337 80 vec */
pascal@12756	10338 );
pascal@12756	10339
pascal@12756	10340 void StateSearchW(
pascal@12756	10341 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	10342 /* (i) Encoder instance */
pascal@12756	10343 float residual,/ (i) target residual vector */
pascal@12756	10344 float syntDenum, / (i) lpc synthesis filter */
pascal@12756	10345 float weightDenum, / (i) weighting filter denuminator */
pascal@12756	10346 int idxForMax, / (o) quantizer index for maximum
pascal@12756	10347 amplitude */
pascal@12756	10348 int idxVec, / (o) vector of quantization indexes */
pascal@12756	10349 int len, /* (i) length of all vectors */
pascal@12756	10350 int state_first /* (i) position of start state in the
pascal@12756	10351 80 vec */
pascal@12756	10352 );
pascal@12756	10353
pascal@12756	10354
pascal@12756	10355 #endif
pascal@12756	10356
pascal@12756	10357
pascal@12756	10358
pascal@12756	10359
pascal@12756	10360
pascal@12756	10361
pascal@12756	10362 Andersen, et al. Experimental [Page 185]
pascal@12756	10363
pascal@12756	10364 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10365
pascal@12756	10366
pascal@12756	10367 A.46. StateSearchW.c
pascal@12756	10368
pascal@12756	10369 /******************************************************************
pascal@12756	10370
pascal@12756	10371 iLBC Speech Coder ANSI-C Source Code
pascal@12756	10372
pascal@12756	10373 StateSearchW.c
pascal@12756	10374
pascal@12756	10375 Copyright (C) The Internet Society (2004).
pascal@12756	10376 All Rights Reserved.
pascal@12756	10377
pascal@12756	10378 ******************************************************************/
pascal@12756	10379
pascal@12756	10380 #include <math.h>
pascal@12756	10381 #include <string.h>
pascal@12756	10382
pascal@12756	10383 #include "iLBC_define.h"
pascal@12756	10384 #include "constants.h"
pascal@12756	10385 #include "filter.h"
pascal@12756	10386 #include "helpfun.h"
pascal@12756	10387
pascal@12756	10388 /----------------------------------------------------------------
pascal@12756	10389 * predictive noise shaping encoding of scaled start state
pascal@12756	10390 * (subrutine for StateSearchW)
pascal@12756	10391 ---------------------------------------------------------------/
pascal@12756	10392
pascal@12756	10393 void AbsQuantW(
pascal@12756	10394 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	10395 /* (i) Encoder instance */
pascal@12756	10396 float in, / (i) vector to encode */
pascal@12756	10397 float syntDenum, / (i) denominator of synthesis filter */
pascal@12756	10398 float weightDenum, / (i) denominator of weighting filter */
pascal@12756	10399 int out, / (o) vector of quantizer indexes */
pascal@12756	10400 int len, /* (i) length of vector to encode and
pascal@12756	10401 vector of quantizer indexes */
pascal@12756	10402 int state_first /* (i) position of start state in the
pascal@12756	10403 80 vec */
pascal@12756	10404 ){
pascal@12756	10405 float *syntOut;
pascal@12756	10406 float syntOutBuf[LPC_FILTERORDER+STATE_SHORT_LEN_30MS];
pascal@12756	10407 float toQ, xq;
pascal@12756	10408 int n;
pascal@12756	10409 int index;
pascal@12756	10410
pascal@12756	10411 /* initialization of buffer for filtering */
pascal@12756	10412
pascal@12756	10413 memset(syntOutBuf, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	10414
pascal@12756	10415
pascal@12756	10416
pascal@12756	10417
pascal@12756	10418 Andersen, et al. Experimental [Page 186]
pascal@12756	10419
pascal@12756	10420 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10421
pascal@12756	10422
pascal@12756	10423 /* initialization of pointer for filtering */
pascal@12756	10424
pascal@12756	10425 syntOut = &syntOutBuf[LPC_FILTERORDER];
pascal@12756	10426
pascal@12756	10427 /* synthesis and weighting filters on input */
pascal@12756	10428
pascal@12756	10429 if (state_first) {
pascal@12756	10430 AllPoleFilter (in, weightDenum, SUBL, LPC_FILTERORDER);
pascal@12756	10431 } else {
pascal@12756	10432 AllPoleFilter (in, weightDenum,
pascal@12756	10433 iLBCenc_inst->state_short_len-SUBL,
pascal@12756	10434 LPC_FILTERORDER);
pascal@12756	10435 }
pascal@12756	10436
pascal@12756	10437 /* encoding loop */
pascal@12756	10438
pascal@12756	10439 for (n=0; n<len; n++) {
pascal@12756	10440
pascal@12756	10441 /* time update of filter coefficients */
pascal@12756	10442
pascal@12756	10443 if ((state_first)&&(n==SUBL)){
pascal@12756	10444 syntDenum += (LPC_FILTERORDER+1);
pascal@12756	10445 weightDenum += (LPC_FILTERORDER+1);
pascal@12756	10446
pascal@12756	10447 /* synthesis and weighting filters on input */
pascal@12756	10448 AllPoleFilter (&in[n], weightDenum, len-n,
pascal@12756	10449 LPC_FILTERORDER);
pascal@12756	10450
pascal@12756	10451 } else if ((state_first==0)&&
pascal@12756	10452 (n==(iLBCenc_inst->state_short_len-SUBL))) {
pascal@12756	10453 syntDenum += (LPC_FILTERORDER+1);
pascal@12756	10454 weightDenum += (LPC_FILTERORDER+1);
pascal@12756	10455
pascal@12756	10456 /* synthesis and weighting filters on input */
pascal@12756	10457 AllPoleFilter (&in[n], weightDenum, len-n,
pascal@12756	10458 LPC_FILTERORDER);
pascal@12756	10459
pascal@12756	10460 }
pascal@12756	10461
pascal@12756	10462 /* prediction of synthesized and weighted input */
pascal@12756	10463
pascal@12756	10464 syntOut[n] = 0.0;
pascal@12756	10465 AllPoleFilter (&syntOut[n], weightDenum, 1,
pascal@12756	10466 LPC_FILTERORDER);
pascal@12756	10467
pascal@12756	10468 /* quantization */
pascal@12756	10469
pascal@12756	10470 toQ = in[n]-syntOut[n];
pascal@12756	10471
pascal@12756	10472
pascal@12756	10473
pascal@12756	10474 Andersen, et al. Experimental [Page 187]
pascal@12756	10475
pascal@12756	10476 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10477
pascal@12756	10478
pascal@12756	10479 sort_sq(&xq, &index, toQ, state_sq3Tbl, 8);
pascal@12756	10480 out[n]=index;
pascal@12756	10481 syntOut[n] = state_sq3Tbl[out[n]];
pascal@12756	10482
pascal@12756	10483 /* update of the prediction filter */
pascal@12756	10484
pascal@12756	10485 AllPoleFilter(&syntOut[n], weightDenum, 1,
pascal@12756	10486 LPC_FILTERORDER);
pascal@12756	10487 }
pascal@12756	10488 }
pascal@12756	10489
pascal@12756	10490 /----------------------------------------------------------------
pascal@12756	10491 * encoding of start state
pascal@12756	10492 ---------------------------------------------------------------/
pascal@12756	10493
pascal@12756	10494 void StateSearchW(
pascal@12756	10495 iLBC_Enc_Inst_t *iLBCenc_inst,
pascal@12756	10496 /* (i) Encoder instance */
pascal@12756	10497 float residual,/ (i) target residual vector */
pascal@12756	10498 float syntDenum, / (i) lpc synthesis filter */
pascal@12756	10499 float weightDenum, / (i) weighting filter denuminator */
pascal@12756	10500 int idxForMax, / (o) quantizer index for maximum
pascal@12756	10501 amplitude */
pascal@12756	10502 int idxVec, / (o) vector of quantization indexes */
pascal@12756	10503 int len, /* (i) length of all vectors */
pascal@12756	10504 int state_first /* (i) position of start state in the
pascal@12756	10505 80 vec */
pascal@12756	10506 ){
pascal@12756	10507 float dtmp, maxVal;
pascal@12756	10508 float tmpbuf[LPC_FILTERORDER+2*STATE_SHORT_LEN_30MS];
pascal@12756	10509 float *tmp, numerator[1+LPC_FILTERORDER];
pascal@12756	10510 float foutbuf[LPC_FILTERORDER+2STATE_SHORT_LEN_30MS], fout;
pascal@12756	10511 int k;
pascal@12756	10512 float qmax, scal;
pascal@12756	10513
pascal@12756	10514 /* initialization of buffers and filter coefficients */
pascal@12756	10515
pascal@12756	10516 memset(tmpbuf, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	10517 memset(foutbuf, 0, LPC_FILTERORDER*sizeof(float));
pascal@12756	10518 for (k=0; k<LPC_FILTERORDER; k++) {
pascal@12756	10519 numerator[k]=syntDenum[LPC_FILTERORDER-k];
pascal@12756	10520 }
pascal@12756	10521 numerator[LPC_FILTERORDER]=syntDenum[0];
pascal@12756	10522 tmp = &tmpbuf[LPC_FILTERORDER];
pascal@12756	10523 fout = &foutbuf[LPC_FILTERORDER];
pascal@12756	10524
pascal@12756	10525 /* circular convolution with the all-pass filter */
pascal@12756	10526
pascal@12756	10527
pascal@12756	10528
pascal@12756	10529
pascal@12756	10530 Andersen, et al. Experimental [Page 188]
pascal@12756	10531
pascal@12756	10532 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10533
pascal@12756	10534
pascal@12756	10535 memcpy(tmp, residual, len*sizeof(float));
pascal@12756	10536 memset(tmp+len, 0, len*sizeof(float));
pascal@12756	10537 ZeroPoleFilter(tmp, numerator, syntDenum, 2*len,
pascal@12756	10538 LPC_FILTERORDER, fout);
pascal@12756	10539 for (k=0; k<len; k++) {
pascal@12756	10540 fout[k] += fout[k+len];
pascal@12756	10541 }
pascal@12756	10542
pascal@12756	10543 /* identification of the maximum amplitude value */
pascal@12756	10544
pascal@12756	10545 maxVal = fout[0];
pascal@12756	10546 for (k=1; k<len; k++) {
pascal@12756	10547
pascal@12756	10548 if (fout[k]fout[k] > maxValmaxVal){
pascal@12756	10549 maxVal = fout[k];
pascal@12756	10550 }
pascal@12756	10551 }
pascal@12756	10552 maxVal=(float)fabs(maxVal);
pascal@12756	10553
pascal@12756	10554 /* encoding of the maximum amplitude value */
pascal@12756	10555
pascal@12756	10556 if (maxVal < 10.0) {
pascal@12756	10557 maxVal = 10.0;
pascal@12756	10558 }
pascal@12756	10559 maxVal = (float)log10(maxVal);
pascal@12756	10560 sort_sq(&dtmp, idxForMax, maxVal, state_frgqTbl, 64);
pascal@12756	10561
pascal@12756	10562 /* decoding of the maximum amplitude representation value,
pascal@12756	10563 and corresponding scaling of start state */
pascal@12756	10564
pascal@12756	10565 maxVal=state_frgqTbl[*idxForMax];
pascal@12756	10566 qmax = (float)pow(10,maxVal);
pascal@12756	10567 scal = (float)(4.5)/qmax;
pascal@12756	10568 for (k=0; k<len; k++){
pascal@12756	10569 fout[k] *= scal;
pascal@12756	10570 }
pascal@12756	10571
pascal@12756	10572 /* predictive noise shaping encoding of scaled start state */
pascal@12756	10573
pascal@12756	10574 AbsQuantW(iLBCenc_inst, fout,syntDenum,
pascal@12756	10575 weightDenum,idxVec, len, state_first);
pascal@12756	10576 }
pascal@12756	10577
pascal@12756	10578
pascal@12756	10579
pascal@12756	10580
pascal@12756	10581
pascal@12756	10582
pascal@12756	10583
pascal@12756	10584
pascal@12756	10585
pascal@12756	10586 Andersen, et al. Experimental [Page 189]
pascal@12756	10587
pascal@12756	10588 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10589
pascal@12756	10590
pascal@12756	10591 A.47. syntFilter.h
pascal@12756	10592
pascal@12756	10593 /******************************************************************
pascal@12756	10594
pascal@12756	10595 iLBC Speech Coder ANSI-C Source Code
pascal@12756	10596
pascal@12756	10597 syntFilter.h
pascal@12756	10598
pascal@12756	10599 Copyright (C) The Internet Society (2004).
pascal@12756	10600 All Rights Reserved.
pascal@12756	10601
pascal@12756	10602 ******************************************************************/
pascal@12756	10603
pascal@12756	10604 #ifndef __iLBC_SYNTFILTER_H
pascal@12756	10605 #define __iLBC_SYNTFILTER_H
pascal@12756	10606
pascal@12756	10607 void syntFilter(
pascal@12756	10608 float Out, / (i/o) Signal to be filtered */
pascal@12756	10609 float a, / (i) LP parameters */
pascal@12756	10610 int len, /* (i) Length of signal */
pascal@12756	10611 float mem / (i/o) Filter state */
pascal@12756	10612 );
pascal@12756	10613
pascal@12756	10614 #endif
pascal@12756	10615
pascal@12756	10616 A.48. syntFilter.c
pascal@12756	10617
pascal@12756	10618 /******************************************************************
pascal@12756	10619
pascal@12756	10620 iLBC Speech Coder ANSI-C Source Code
pascal@12756	10621
pascal@12756	10622 syntFilter.c
pascal@12756	10623
pascal@12756	10624 Copyright (C) The Internet Society (2004).
pascal@12756	10625 All Rights Reserved.
pascal@12756	10626
pascal@12756	10627 ******************************************************************/
pascal@12756	10628
pascal@12756	10629 #include "iLBC_define.h"
pascal@12756	10630
pascal@12756	10631 /----------------------------------------------------------------
pascal@12756	10632 * LP synthesis filter.
pascal@12756	10633 ---------------------------------------------------------------/
pascal@12756	10634
pascal@12756	10635 void syntFilter(
pascal@12756	10636 float Out, / (i/o) Signal to be filtered */
pascal@12756	10637 float a, / (i) LP parameters */
pascal@12756	10638 int len, /* (i) Length of signal */
pascal@12756	10639
pascal@12756	10640
pascal@12756	10641
pascal@12756	10642 Andersen, et al. Experimental [Page 190]
pascal@12756	10643
pascal@12756	10644 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10645
pascal@12756	10646
pascal@12756	10647 float mem / (i/o) Filter state */
pascal@12756	10648 ){
pascal@12756	10649 int i, j;
pascal@12756	10650 float po, pi, pa, pm;
pascal@12756	10651
pascal@12756	10652 po=Out;
pascal@12756	10653
pascal@12756	10654 /* Filter first part using memory from past */
pascal@12756	10655
pascal@12756	10656 for (i=0; i<LPC_FILTERORDER; i++) {
pascal@12756	10657 pi=&Out[i-1];
pascal@12756	10658 pa=&a[1];
pascal@12756	10659 pm=&mem[LPC_FILTERORDER-1];
pascal@12756	10660 for (j=1; j<=i; j++) {
pascal@12756	10661 po-=(pa++)(pi--);
pascal@12756	10662 }
pascal@12756	10663 for (j=i+1; j<LPC_FILTERORDER+1; j++) {
pascal@12756	10664 po-=(pa++)(pm--);
pascal@12756	10665 }
pascal@12756	10666 po++;
pascal@12756	10667 }
pascal@12756	10668
pascal@12756	10669 /* Filter last part where the state is entirely in
pascal@12756	10670 the output vector */
pascal@12756	10671
pascal@12756	10672 for (i=LPC_FILTERORDER; i<len; i++) {
pascal@12756	10673 pi=&Out[i-1];
pascal@12756	10674 pa=&a[1];
pascal@12756	10675 for (j=1; j<LPC_FILTERORDER+1; j++) {
pascal@12756	10676 po-=(pa++)(pi--);
pascal@12756	10677 }
pascal@12756	10678 po++;
pascal@12756	10679 }
pascal@12756	10680
pascal@12756	10681 /* Update state vector */
pascal@12756	10682
pascal@12756	10683 memcpy(mem, &Out[len-LPC_FILTERORDER],
pascal@12756	10684 LPC_FILTERORDER*sizeof(float));
pascal@12756	10685 }
pascal@12756	10686
pascal@12756	10687
pascal@12756	10688
pascal@12756	10689
pascal@12756	10690
pascal@12756	10691
pascal@12756	10692
pascal@12756	10693
pascal@12756	10694
pascal@12756	10695
pascal@12756	10696
pascal@12756	10697
pascal@12756	10698 Andersen, et al. Experimental [Page 191]
pascal@12756	10699
pascal@12756	10700 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10701
pascal@12756	10702
pascal@12756	10703 Authors' Addresses
pascal@12756	10704
pascal@12756	10705 Soren Vang Andersen
pascal@12756	10706 Department of Communication Technology
pascal@12756	10707 Aalborg University
pascal@12756	10708 Fredrik Bajers Vej 7A
pascal@12756	10709 9200 Aalborg
pascal@12756	10710 Denmark
pascal@12756	10711
pascal@12756	10712 Phone: ++45 9 6358627
pascal@12756	10713 EMail: sva@kom.auc.dk
pascal@12756	10714
pascal@12756	10715
pascal@12756	10716 Alan Duric
pascal@12756	10717 Telio AS
pascal@12756	10718 Stoperigt. 2
pascal@12756	10719 Oslo, N-0250
pascal@12756	10720 Norway
pascal@12756	10721
pascal@12756	10722 Phone: +47 21673555
pascal@12756	10723 EMail: alan.duric@telio.no
pascal@12756	10724
pascal@12756	10725
pascal@12756	10726 Henrik Astrom
pascal@12756	10727 Global IP Sound AB
pascal@12756	10728 Olandsgatan 42
pascal@12756	10729 Stockholm, S-11663
pascal@12756	10730 Sweden
pascal@12756	10731
pascal@12756	10732 Phone: +46 8 54553040
pascal@12756	10733 EMail: henrik.astrom@globalipsound.com
pascal@12756	10734
pascal@12756	10735
pascal@12756	10736 Roar Hagen
pascal@12756	10737 Global IP Sound AB
pascal@12756	10738 Olandsgatan 42
pascal@12756	10739 Stockholm, S-11663
pascal@12756	10740 Sweden
pascal@12756	10741
pascal@12756	10742 Phone: +46 8 54553040
pascal@12756	10743 EMail: roar.hagen@globalipsound.com
pascal@12756	10744
pascal@12756	10745
pascal@12756	10746
pascal@12756	10747
pascal@12756	10748
pascal@12756	10749
pascal@12756	10750
pascal@12756	10751
pascal@12756	10752
pascal@12756	10753
pascal@12756	10754 Andersen, et al. Experimental [Page 192]
pascal@12756	10755
pascal@12756	10756 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10757
pascal@12756	10758
pascal@12756	10759 W. Bastiaan Kleijn
pascal@12756	10760 Global IP Sound AB
pascal@12756	10761 Olandsgatan 42
pascal@12756	10762 Stockholm, S-11663
pascal@12756	10763 Sweden
pascal@12756	10764
pascal@12756	10765 Phone: +46 8 54553040
pascal@12756	10766 EMail: bastiaan.kleijn@globalipsound.com
pascal@12756	10767
pascal@12756	10768
pascal@12756	10769 Jan Linden
pascal@12756	10770 Global IP Sound Inc.
pascal@12756	10771 900 Kearny Street, suite 500
pascal@12756	10772 San Francisco, CA-94133
pascal@12756	10773 USA
pascal@12756	10774
pascal@12756	10775 Phone: +1 415 397 2555
pascal@12756	10776 EMail: jan.linden@globalipsound.com
pascal@12756	10777
pascal@12756	10778
pascal@12756	10779
pascal@12756	10780
pascal@12756	10781
pascal@12756	10782
pascal@12756	10783
pascal@12756	10784
pascal@12756	10785
pascal@12756	10786
pascal@12756	10787
pascal@12756	10788
pascal@12756	10789
pascal@12756	10790
pascal@12756	10791
pascal@12756	10792
pascal@12756	10793
pascal@12756	10794
pascal@12756	10795
pascal@12756	10796
pascal@12756	10797
pascal@12756	10798
pascal@12756	10799
pascal@12756	10800
pascal@12756	10801
pascal@12756	10802
pascal@12756	10803
pascal@12756	10804
pascal@12756	10805
pascal@12756	10806
pascal@12756	10807
pascal@12756	10808
pascal@12756	10809
pascal@12756	10810 Andersen, et al. Experimental [Page 193]
pascal@12756	10811
pascal@12756	10812 RFC 3951 Internet Low Bit Rate Codec December 2004
pascal@12756	10813
pascal@12756	10814
pascal@12756	10815 Full Copyright Statement
pascal@12756	10816
pascal@12756	10817 Copyright (C) The Internet Society (2004).
pascal@12756	10818
pascal@12756	10819 This document is subject to the rights, licenses and restrictions
pascal@12756	10820 contained in BCP 78, and except as set forth therein, the authors
pascal@12756	10821 retain all their rights.
pascal@12756	10822
pascal@12756	10823 This document and the information contained herein are provided on an
pascal@12756	10824 "AS IS" basis and THE CONTRIBUTOR, THE ORGANIZATION HE/SHE REPRESENTS
pascal@12756	10825 OR IS SPONSORED BY (IF ANY), THE INTERNET SOCIETY AND THE INTERNET
pascal@12756	10826 ENGINEERING TASK FORCE DISCLAIM ALL WARRANTIES, EXPRESS OR IMPLIED,
pascal@12756	10827 INCLUDING BUT NOT LIMITED TO ANY WARRANTY THAT THE USE OF THE
pascal@12756	10828 INFORMATION HEREIN WILL NOT INFRINGE ANY RIGHTS OR ANY IMPLIED
pascal@12756	10829 WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE.
pascal@12756	10830
pascal@12756	10831 Intellectual Property
pascal@12756	10832
pascal@12756	10833 The IETF takes no position regarding the validity or scope of any
pascal@12756	10834 Intellectual Property Rights or other rights that might be claimed to
pascal@12756	10835 pertain to the implementation or use of the technology described in
pascal@12756	10836 this document or the extent to which any license under such rights
pascal@12756	10837 might or might not be available; nor does it represent that it has
pascal@12756	10838 made any independent effort to identify any such rights. Information
pascal@12756	10839 on the IETF's procedures with respect to rights in IETF Documents can
pascal@12756	10840 be found in BCP 78 and BCP 79.
pascal@12756	10841
pascal@12756	10842 Copies of IPR disclosures made to the IETF Secretariat and any
pascal@12756	10843 assurances of licenses to be made available, or the result of an
pascal@12756	10844 attempt made to obtain a general license or permission for the use of
pascal@12756	10845 such proprietary rights by implementers or users of this
pascal@12756	10846 specification can be obtained from the IETF on-line IPR repository at
pascal@12756	10847 http://www.ietf.org/ipr.
pascal@12756	10848
pascal@12756	10849 The IETF invites any interested party to bring to its attention any
pascal@12756	10850 copyrights, patents or patent applications, or other proprietary
pascal@12756	10851 rights that may cover technology that may be required to implement
pascal@12756	10852 this standard. Please address the information to the IETF at ietf-
pascal@12756	10853 ipr@ietf.org.
pascal@12756	10854
pascal@12756	10855
pascal@12756	10856 Acknowledgement
pascal@12756	10857
pascal@12756	10858 Funding for the RFC Editor function is currently provided by the
pascal@12756	10859 Internet Society.
pascal@12756	10860
pascal@12756	10861
pascal@12756	10862
pascal@12756	10863
pascal@12756	10864
pascal@12756	10865
pascal@12756	10866 Andersen, et al. Experimental [Page 194]
pascal@12756	10867

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