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view wdf/wdf_tl.c @ 0:5242703e91d3 tip
Initial checkin for AIM92 aimR8.2 (last updated May 1997).
| author | tomwalters |
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| date | Fri, 20 May 2011 15:19:45 +0100 |
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/* Copyright (c) Applied Psychology Unit, Medical Research Council. 1988, 1989 =========================================================================== Permission to use, copy, modify, and distribute this software without fee is hereby granted for research purposes, provided that this copyright notice appears in all copies and in all supporting documentation, and that the software is not redistributed for any fee (except for a nominal shipping charge). Anyone wanting to incorporate all or part of this software in a commercial product must obtain a license from the Medical Research Council. The MRC makes no representations about the suitability of this software for any purpose. It is provided "as is" without express or implied warranty. THE MRC DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL THE A.P.U. BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ /* Acknowledgment: ============== The source code provided in this file was originally developed by Christian Giguere as part of a Ph.D degree at the Department of Engineering of the University of Cambridge from April 1990 to November 1993. The code was subsequently adapted under a grant from the Hearing Research Trust for full compatibility with AIM Release 6.15. Christian Giguere 25/03/94 */ /* ============================================================= wdf_tl.c ============================================================= Wave digital filter (WDF) implementation of the cochlear transmission line (TL) network. Author : Christian Giguere First written : 01st April, 1991 Last edited : 18th February, 1994 References: (1) C.Giguere and P.C.Woodland (1994). JASA 95(1): 331-342. (2) A.Fettweis (1986). Proceedings IEEE 74(2): 270-327. ============================================================= */ /***** includes *****/ #include <math.h> #include <stdio.h> #include "stitch.h" #include "source.h" #include "calc.h" #include "calc_tl.h" #include "bank_tl.h" #include "wdf_tl.h" #include "wdf_ear.h" /***** defines *****/ #if 0 #define _DEBUG_ #define _OVERFLOW_ #endif #if 0 #define _IMPULSE_ /* bypasses input wave with a delta impulse */ #endif #if 0 /* bypasses input wave with a pure tone and dumps */ #define _BMCURVES_ /* the rms value of basilar membrane velocity on stdout */ #endif /* (see below for other parameters to set) */ #if 0 #define _EAR_ /* dumps stapes velocity and eardrum pressure on stdout */ #endif #define NUMBER_OF_STATES ( 14 ) /* per TLF segment */ #define NUMBER_OF_COEFFS ( 0 ) /* per TLF segment */ /***** functions *****/ /******************************** WDF set-up function ************************************* * name: function: * * WDFilterState() Set-up function for the WDF implementation of the cochlear network * (Giguere and Woodland, 1994, Figs. 3 and 10). It generates the * multiplier coefficients and initializes the states of the filter. * It is called by function ``TLF_GenBank()'' in file ``bank_tl.c'' * once for each segment of the transmission line starting from the most * apical segment. It returns a pointer to a structure containing all * the relevant information for the computation of the current filter * segment. * * Note: The code that sets up the WDF implementation of the outer ear * and middle ear is located in file ``wdf_ear.c''. ******************************************************************************************/ /************************************ WDFilterState() ************************************/ WDFilterState *WDFilter( samplerate, center_frequency, scale_vel, scale_disp, rho, scala_area, width, qfactor, mass_per_area, seglength, Lt, warping, active, zov, OHC_gain, OHC_sat ) double samplerate, center_frequency, scale_vel, scale_disp ; double rho, scala_area, width, qfactor, mass_per_area, seglength, Lt ; int warping, active ; double *zov, OHC_gain, OHC_sat ; { static int apex = 1 ; DeclareNew( WDFilterState *, filter_state ) ; CoeffType *cf ; double an, bn, mn, d, fs, fn ; double Lsn, Ln, Cn, Rn ; double r1, r2, r3, r4, g1, g2, g3, zn, zcn ; /***** cochlear parameters for current BM segment *****/ an = scala_area ; /* cross-sectional area of each scala (cm2) */ bn = width ; /* BM width (cm) */ mn = mass_per_area ; /* transversal mass-per-area-of-BM (g/cm2) */ d = seglength ; /* BM segment length (cm) */ /***** frequency warping compensation due to bilinear transform *****/ fs = samplerate ; if ( warping == 0 ) fn = center_frequency ; else fn = fs / Pi * tan( Pi * center_frequency / fs ) ; /***** electrical circuit elements (CGS units) for current segment *****/ Ln = mn / ( bn * d ) ; /* shunt inductor */ Cn = 1. / ( ( TwoPi * TwoPi * fn * fn ) * Ln ) ; /* shunt capacitor */ Rn = sqrt( Ln / Cn ) / qfactor ; /* shunt resistor */ Lsn = ( 2. * rho * d ) / an ; /* series inductor */ /***** WDF multiplier coefficients for current TL segment *****/ /*** initialise filter coeffs ***/ filter_state->coeffs = ( char * ) NewZeroedArray( CoeffType, NUMBER_OF_COEFFS, "wdf_tl.c for filter coeffs\n" ) ; cf = ( CoeffType * ) filter_state->coeffs ; /* Adaptor 25 */ r1 = zcn = 1. / (2. * fs * Cn ) ; /* Zcn */ r2 = Rn ; /* Zrn */ r3 = 2. * fs * Ln ; /* Zln */ r4 = zn = r1 + r2 + r3 ; filter_state->gamma251 = r1 / r4 ; filter_state->gamma252 = r2 / r4 ; /* Adaptor 24 */ g1 = 1. / zn ; if( apex ) { g2 = 1. / ( 2. * fs * Lt ) ; /* (1 / Zlt) */ apex = 0 ; } else g2 = 1. / *zov ; /* Zov (at the base) */ g3 = g1 + g2 ; filter_state->gamma241 = g1 / g3 ; /* Adaptor 23 */ r1 = 2. * fs * Lsn ; /* Zlsn */ r2 = 1. / g3 ; r3 = *zov = r1 + r2 ; /* Zov */ filter_state->gamma231 = r1 / r3 ; #ifdef _DEBUG_ fprintf( stderr, "gamma251=%f gamma252=%f\n", filter_state->gamma251 , filter_state->gamma252 ) ; fprintf( stderr, "gamma241=%f \n", filter_state->gamma241 ) ; fprintf( stderr, "gamma231=%f \n", filter_state->gamma231 ) ; #endif /***** scaling to convert output to transversal motion of BM segment *****/ filter_state->out_scale_disp = scale_disp * Cn / ( 2. * bn * d ) ; filter_state->out_scale_vel = scale_vel / ( 2. * zcn * bn * d ) ; /***** multiplier coefficients for OHC source *****/ filter_state->OHC_sat = OHC_sat * scale_disp / filter_state->out_scale_disp ; filter_state->OHC_gain = - OHC_gain * Rn * filter_state->OHC_sat / ( 2. * zcn ) ; #ifdef _BMCURVES_ /***** initialise rms detection *****/ filter_state->rms = 0.0 ; filter_state->sample = 0 ; #endif /***** initialise filter states *****/ filter_state->states = ( char * ) NewZeroedArray( StateType, NUMBER_OF_STATES, "wdf_tl.c for filter states\n" ) ; /***** is channel active for display ? *****/ filter_state->active = active ; /***** return *****/ return( filter_state ) ; } /*********************************** WDF procedures *************************************** * name: function: * * DoWDFdataArray() WDF realization of the outer ear, middle ear and cochlear networks. * It is called by function ``tlf_bank_callback()'' in file ``bank_tl.c'' * once for a specified number of input points. It computes the BM * displacement or velocity for each segment and keeps track of the * filter states. * * CloseWDF() Deletes all private data structures and arrays of the cochlear * transmission line filter upon completion of filtering. It is called * by function ``tlf_bank_callbank()'' in file ``bank_tl.c''. ******************************************************************************************/ /********************************** DoWDFdataArray() **********************************/ void DoWDFdataArray( bankInfo, filter_states, input, output, points, channels, ws, eartube_states, ms, tube_segments ) register TLF_BankInfo *bankInfo ; register WDFilterState **filter_states ; register DataType *input ; register DataType *output ; register int points, channels ; register WaveWDFstate *ws ; register EartubeWDFstate **eartube_states ; register EarmiddleWDFstate *ms ; register int tube_segments ; { register WDFilterState *fs ; register EartubeWDFstate *ts ; register StateType *st ; register StateType dn, in, out ; register StateType a0, an_1, b1, b2, b3, b63, b161, b202, b212 ; static StateType bn = 0. ; register CoeffType *cf ; register int decimateCount = bankInfo->decimateCount ; register int decimate_factor = bankInfo->decimate_factor ; register int channelActive, pointActive, motion = bankInfo->output_var ; register int channel = -1, tube_segment = -1 ; #ifdef _BMCURVES_ static long sample = -1 ; int period = 48 ; /* in samples */ double samplerate = 48000. ; /* samples per sec */ double rise_time = 2.0 ; /* sec */ double start_time = 4.0 ; /* sec */ #endif #ifdef _IMPULSE_ static int impulse = 10000 ; #endif /***** update stapedial muscle state *****/ ( void ) ms->update_proc( ms ) ; /***** for all points ******/ #ifdef _DEBUG_ fprintf( stderr, "DoWDFdataArray() = %d points X %d channels\n", points, channels ) ; #endif while( points-- > 0 ) { if( decimateCount == decimate_factor ) decimateCount = 0 ; pointActive = !decimateCount ; decimateCount++ ; output += bankInfo->output_chans * pointActive ; /*** for all TL channels in BACKWARD direction for current input point ***/ while( ++channel < channels ) { /* get states and coefficients */ fs = *filter_states++ ; st = ( StateType * ) fs->states ; cf = ( CoeffType * ) fs->coeffs ; /* Adaptor 25 */ st[10] = st[1] ; /* a251 */ st[3] = st[2] - st[4] - st[1] ; /* b254 = a221 */ /* Adaptor 24 */ st[9] = bn ; /* -a242 */ st[5] = fs->gamma241 * ( st[3] + st[9] ) ; /* b240 */ st[6] = st[5] - st[9] ; /* b243 = a232 */ /* Adaptor 23 */ st[7] = st[8] - st[6] ; /* b233 */ bn = st[7] ; } /*** input point ***/ in = ( StateType ) *input++ ; #ifdef _IMPULSE_ if( impulse != 0 ) { in = ( StateType ) impulse ; impulse = 0 ; } else in = ( StateType ) 0 ; #endif #ifdef _BMCURVES_ if( ++sample < ( long ) ( samplerate * rise_time ) ) in = 0.28284 * ( double ) sample / ( samplerate * rise_time ) * sin( TwoPi * ( double ) ( sample % period ) / ( double ) period ) ; else in = 0.28284 * sin( TwoPi * ( double ) ( sample % period ) / ( double ) period ) ; #endif /*** computation of outer and middle ear in FORWARD direction for current input point ***/ /* freefield - external ear */ /* get states */ st = ( StateType * ) ws->states ; /* Adaptor 0 */ st[4] = ws->gamma01 * ( st[3] - in ) ; /* b00 */ st[5] = st[4] + in + in ; /* b03 = -a11 */ /* Adaptor 2 */ st[1] = -ws->gamma21 * st[0] ; /* b20 */ st[2] = st[1] ; /* b23 = a12 */ /* Adaptor 1 */ st[6] = st[5] - st[2] ; /* b13 = a32 */ an_1 = st[6] ; /* concha and auditory canal */ while( ++tube_segment < tube_segments ) { /* get states */ ts = *eartube_states++ ; st = ( StateType * ) ts->states ; /* Adaptor 3 */ st[3] = st[4] - an_1 ; /* b33 = a41 */ /* Adaptor 5 */ st[0] = -ts->gamma51 * st[1] ; /* b50 */ st[2] = st[0] + st[1] ; /* b53 = a42 */ /* Adaptor 4 */ st[5] = st[3] - st[2] ; /* -a42+a41 */ st[6] = ts->gamma41 * st[5] ; /* b40 */ st[7] = st[6] + st[2] ; /* b43 = a61 */ /* Adaptor 6 */ st[8] = st[9] - st[7] ; /* b63 = a32 */ an_1 = b63 = st[8] ; } /* middle ear */ /* get states */ st = ( StateType * ) ms->states ; /* Adaptor 9 */ st[31] = st[30] - st[29] ; /* b94 = a81 */ /* Adaptor 8 */ st[32] = st[35] - st[31] ; /* a83-a81 */ st[33] = -ms->gamma81 * st[32] - ms->gamma82 * st[35] ; /* b80 */ st[34] = st[33] + st[35] ; /* b84 = a71 */ /* Adaptor 7 */ st[36] = -st[34] - an_1 ; /* b73 = a102 */ /* Adaptor 13 */ st[15] = -st[14] ; /* b133 = a122 */ /* Adaptor 12 */ st[16] = st[15] + st[18] ; /* a122-a121 */ st[17] = -ms->gamma121 * st[16] ; /* b120 */ st[19] = st[17] + st[15] ; /* b123 = a112 */ /* Adaptor 14 */ st[21] = -ms->gamma141 * st[20] ; /* b140 */ st[22] = st[21] + st[20] ; /* b143 = a111 */ /* Adaptor 15 */ st[23] = -st[24] ; /* b153 = a113 */ /* Adaptor 11 */ st[25] = -st[22] - st[19] - st[23] ; /* b114 = a101 */ /* Adaptor 10 */ st[26] = st[25] - st[36] ; /* -a102+a101 */ st[27] = ms->gamma101 * st[26] ; /* b100 */ st[28] = st[27] + st[36] ; /* b103 = a161 */ /* Adaptor 17 */ st[10] = st[12] - st[11] ; /* b174 = a162 */ /* Adaptor 16 */ st[13] = -st[28] - st[10] ; /* b163 = a181 */ /* Adaptor 19 */ st[5] = -st[6] ; /* b193 = a182 */ /* Adaptor 18 */ st[7] = st[13] - st[5] ; /* -a182+a181 */ st[8] = ms->gamma181 * st[7] ; /* b180 */ st[9] = st[8] + st[5] ; /* b183 = a203 */ /* Adaptor 20 */ st[40] = - bn / ms->ratio ; /* a202 */ st[3] = -st[40] - st[9] ; /* b204 = a212 */ /* Adaptor 21 */ st[0] = st[2] - st[1] - st[3] ; /* b214 = a222 */ /*** computation of outer and middle ear in BACKWARD direction for current input point ***/ /* middle ear */ /* Adaptor 22 */ a0 = st[4] + st[0] ; /* a220 */ st[4] = st[4] - ms->gamma221 * a0 ; /* b221 */ b2 = -st[4] - a0 ; /* b222 = a214 */ /* Adaptor 21 */ a0 = b2 - st[0] ; /* a210 */ st[1] = st[1] - ms->gamma211 * a0 ; /* b211 */ b212 = st[3] - ms->gamma212 * a0 ; /* b212 = a204 */ st[2] = -st[1] - b212 - b2 ; /* b213 */ /* Adaptor 20 */ a0 = b212 - st[3] ; /* a200 */ b202 = st[40] - ms->gamma202 * a0 ; /* b202 */ b3 = ms->gamma201 * a0 - b202 - b212 ; /* b203 = a183 */ /* Adaptor 18 */ b2 = st[8] + b3 ; /* b182 = a193 */ b1 = b2 - st[7] ; /* b181 = a163 */ /* Adaptor 19 */ st[6] = st[6] + ms->gamma191 * ( st[5] - b2 ) ; /* b191 */ /* Adaptor 16 */ b161 = st[28] + ms->gamma161 * ( st[13] - b1 ) ; /* b161 = a103 */ b2 = -b161 - b1 ; /* b162 = a174 */ /* Adaptor 17 */ a0 = b2 - st[10] ; /* a170 */ st[11] = st[11] - ms->gamma171 * a0 ; /* b171 */ st[12] = ms->gamma172 * a0 - b2 - st[11] ; /* b173 */ /* Adaptor 10 */ st[37] = st[27] + b161 ; /* b102 = a73 */ st[38] = st[37] - st[26] ; /* b101 = a114 */ /* Adaptor 11 */ a0 = st[38] - st[25] ; /* a110 */ b1 = st[22] - ms->gamma111 * a0 ; /* b111 = a143 */ b2 = st[19] - ms->gamma112 * a0 ; /* b112 = a123 */ b3 = -b1 -b2 - st[38] ; /* b113 = a153 */ /* Adaptor 15 */ st[24] = st[24] + ms->gamma151 * ( st[23] - b3 ) ; /* b151 */ /* Adaptor 14 */ st[20] = st[21] + b1 ; /* b142 */ /* Adaptor 12 */ b2 = st[17] + b2 ; /* b122 = a133 */ st[18] = b2 + st[16] ; /* b121 */ /* Adaptor 13 */ st[14] = st[14] + ms->gamma131 * ( st[15] - b2 ) ; /* b131 */ /* Adaptor 7 */ b1 = st[34] + ms->gamma71 * ( st[36] - st[37] ) ; /* b71 = a84 */ st[39] = -b1 - st[37] ; /* b72 = a63 */ /* Adaptor 8 */ st[35] = st[33] + b1 ; /* b83 */ b1 = st[35] + st[32] ; /* b81 = a94 */ /* Adaptor 9 */ a0 = b1 - st[31] ; /* a90 */ st[29] = st[29] - ms->gamma91 * a0 ; /* b91 */ st[30] = -st[29] + ms->gamma92 * a0 - b1 ; /* b93 */ bn = st[39] ; /* concha and auditory canal */ while( tube_segment-- > 0 ) { /* get states */ ts = *--eartube_states ; st = ( StateType * ) ts->states ; /* Adaptor 6 */ b1 = st[7] - ts->gamma61 * ( bn - st[8] ) ; /* b61 = a43 */ st[9] = -b1 - bn ; /* b62 */ /* Adaptor 4 */ b2 = st[6] + b1 ; /* b42 = a53 */ b1 = b2 - st[5] ; /* b41 = a33 */ /* Adaptor 5 */ st[1] = st[0] + b2 ; /* b52 */ /* Adaptor 3 */ st[4] = ts->gamma31 * ( st[3] - b1 ) - st[4] ; /* b31 */ bn = -st[4] - b1 ; /* b32 = a63 */ } /* freefield - external ear */ /* get states */ st = ( StateType * ) ws->states ; /* Adaptor 1 */ b1 = ws->gamma11 * ( st[6] - bn ) - st[5] ; /* b11 = -a03 */ b2 = -b1 - bn ; /* b12 = a23 */ /* Adaptor 2 */ st[0] = st[1] + b2 + st[0] ; /* b61 */ /* Adaptor 0 */ st[3] = b1 - st[4] + st[3] ; /* -b01 + p */ an_1 = - b202 * ms->ratio ; /* for all channels in FORWARD direction for current input point */ while( channel-- > 0 ) { /* get states and coefficients */ fs = *--filter_states ; st = ( StateType * ) fs->states ; cf = ( CoeffType * ) fs->coeffs ; channelActive = fs->active ; /* Adaptor 23 */ st[8] = fs->gamma231 * ( st[7] - an_1 ) - st[8] ; /* b231 */ b2 = an_1 + st[8] ; /* -b232 = -a243 */ /* Adaptor 24 */ an_1 = b2 - st[5] ; /* -b242 */ b1 = -an_1 - st[3] - st[9] ; /* b241 = a254 */ /* Adaptor 25 */ a0 = b1 - st[3] ; /* a250 */ st[1] = st[10] - fs->gamma251 * a0 ; /* b251 */ st[2] = fs->gamma252 * a0 - st[4] - st[1] - b1 ; /* b253 */ dn = st[1] + st[10] ; in = st[1] - st[10] ; /* output storage */ if( channelActive * pointActive ) { if( motion == DISPLACEMENT ) out = fs->out_scale_disp * dn ; else out = fs->out_scale_vel * in ; #ifdef _OVERFLOW_ if( out > _MaxOutput_ || out < _MinOutput_ ) fprintf( stderr, "Overflow error in BMM output=%e\n", ( double ) out ) ; #endif *(--output) = ( DataType ) ( out ) ; } /* OHC nonlinear voltage source */ if( dn < 0. ) dn = -dn ; st[4] = fs->OHC_gain * in / ( fs->OHC_sat + dn ) ; /* -Vn(ohc) */ #ifdef _BMCURVES_ if( sample > ( long ) ( start_time * samplerate ) ) { in = fs->out_scale_vel * in ; fs->rms = fs->rms + in*in ; fs->sample++ ; } #endif } bn = -an_1 ; /* apical boundary condition */ output += bankInfo->output_chans * pointActive ; #ifdef _EAR_ st = ( StateType * ) ms->states ; printf( "stapes=%e eardrum=%e\n", 0.5 * ( st[40] - b202 ), 0.5 * ( st[39] + b63 ) ) ; #endif } return ; } /******************************* CloseWDF() *************************************/ void CloseWDF( states, channels, bank ) register WDFilterState **states ; register int channels ; register TLF_BankInfo *bank ; { int channel ; for( channel = 0 ; channel < channels ; channel++ ) { #ifdef _BMCURVES_ printf( "%d %e\n", channel+1, sqrt(states[channel]->rms / states[channel]->sample) ) ; #endif Delete( states[channel]->states ) ; Delete( states[channel]->coeffs ) ; } Delete( states ) ; Delete( bank ) ; return ; }