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annotate toolboxes/MIRtoolbox1.3.2/AuditoryToolbox/SeneffEarSetup.m @ 0:cc4b1211e677 tip

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initial commit to HG from Changeset: 646 (e263d8a21543) added further path and more save "camirversion.m"
author Daniel Wolff
date Fri, 19 Aug 2016 13:07:06 +0200
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Daniel@0 1 function [SeneffPreemphasis, SeneffFilterBank, SeneffForward, SeneffBackward] ...
Daniel@0 2 = SeneffEarSetup(fs)
Daniel@0 3
Daniel@0 4 % This m-function is based on data from the following paper:
Daniel@0 5 % Benjamin D. Bryant and John D. Gowdy, "Simulation of Stages
Daniel@0 6 % I and II of Seneff's Auditory Model (SAM) Using Matlab", and
Daniel@0 7 % published in the Proceedings of the 1993 Matlab User's Group
Daniel@0 8 % Conference.
Daniel@0 9 % Thanks to Benjamin Bryant for supplying us with his filter
Daniel@0 10 % coefficients and the initial organization of this implementation.
Daniel@0 11
Daniel@0 12 % (c) 1998 Interval Research Corporation
Daniel@0 13
Daniel@0 14 % Set the following variable to a non-zero value to see a summary
Daniel@0 15 % of the filter bank's behaviour.
Daniel@0 16 plotTests = 0;
Daniel@0 17
Daniel@0 18 % The following values were taken from Figure 2 of Bryant's paper.
Daniel@0 19 PreemphasisRTheta = [0.86 3.1148863;0.99 0; 0.5 0; 0.95 3.14159];
Daniel@0 20
Daniel@0 21 % The following values were taken from Table 1 of Bryant's paper.
Daniel@0 22 % They represent the cascade zeros (R-z and Theta-z), and the
Daniel@0 23 % second order poles (radius and theta) and zeros (radius and theta/2).
Daniel@0 24 %
Daniel@0 25 % R-z Theta-z Radius Theta R-z2
Daniel@0 26 FilterBankRTheta = [
Daniel@0 27 0 3.14159 0.740055 2.633909 0.8
Daniel@0 28 0.86 2.997077 0.753637 2.178169 0.8
Daniel@0 29 0.86 2.879267 0.775569 1.856744 0.8
Daniel@0 30 0.86 2.761458 0.798336 1.617919 0.8
Daniel@0 31 0.86 2.643648 0.819169 1.433496 0.8
Daniel@0 32 0.86 2.525839 0.837158 1.286795 0.8
Daniel@0 33 0.8 2.964876 0.852598 1.167321 0.8
Daniel@0 34 0.86 2.408029 0.865429 1.068141 0.8
Daniel@0 35 0.86 2.29022 0.876208 0.984489 0.8
Daniel@0 36 0.86 2.17241 0.885329 0.912985 0.8
Daniel@0 37 0.86 2.054601 0.893116 0.851162 0.8
Daniel@0 38 0.86 1.936791 0.899823 0.797179 0.8
Daniel@0 39 0.8 2.788161 0.906118 0.749633 0.8
Daniel@0 40 0.86 1.818981 0.911236 0.70744 0.8
Daniel@0 41 0.86 1.701172 0.915747 0.669742 0.8
Daniel@0 42 0.86 1.583362 0.919753 0.635858 0.8
Daniel@0 43 0.86 1.465552 0.923335 0.605237 0.8
Daniel@0 44 0.86 1.347743 0.926565 0.57743 0.8
Daniel@0 45 0.8 2.611447 0.929914 0.552065 0.8
Daniel@0 46 0.86 1.229933 0.932576 0.528834 0.8
Daniel@0 47 0.86 1.112123 0.944589 0.487783 0.75
Daniel@0 48 0.86 0.994314 0.957206 0.452645 0.660714
Daniel@0 49 0.86 0.876504 0.956548 0.42223 0.672143
Daniel@0 50 0.86 0.758694 0.956653 0.395644 0.682143
Daniel@0 51 0.8 2.434732 0.956518 0.372208 0.690966
Daniel@0 52 0.86 0.640885 0.956676 0.351393 0.69881
Daniel@0 53 0.86 0.523075 0.956741 0.316044 0.712143
Daniel@0 54 0.8 2.258018 0.956481 0.287157 0.723052
Daniel@0 55 0.8 2.081304 0.956445 0.263108 0.732143
Daniel@0 56 0.8 1.904589 0.956481 0.242776 0.739835
Daniel@0 57 0.86 0.405265 0.958259 0.217558 0.749384
Daniel@0 58 0.8 1.727875 0.963083 0.197086 0.757143
Daniel@0 59 0.8 1.55116 0.969757 0.175115 0.769048
Daniel@0 60 0.8 1.374446 0.97003 0.153697 0.780662
Daniel@0 61 0.8 1.197732 0.970382 0.134026 0.791337
Daniel@0 62 0.8 1.021017 0.970721 0.118819 0.799596
Daniel@0 63 0.8 1.5 0.970985 0.106711 0.8
Daniel@0 64 0.8 1.2 0.971222 0.096843 0.8
Daniel@0 65 0.8 1 0.97144 0.088645 0.8
Daniel@0 66 0.8 0.9 0.971645 0.081727 0.8];
Daniel@0 67
Daniel@0 68 % Let's plot the cascade zero locations and the locations of the
Daniel@0 69 % pole and zeros in the resonator.
Daniel@0 70 if plotTests
Daniel@0 71 clf;
Daniel@0 72 subplot(3,3,1);
Daniel@0 73 plot(FilterBankRTheta(:,1).*exp(i*FilterBankRTheta(:,2)))
Daniel@0 74 axis([-1 1 0 1])
Daniel@0 75 title('Cascade Zero Locations')
Daniel@0 76
Daniel@0 77 subplot(3,3,2);
Daniel@0 78 plot([FilterBankRTheta(:,3).*exp(i*FilterBankRTheta(:,4)) ...
Daniel@0 79 FilterBankRTheta(:,5).*exp(i*FilterBankRTheta(:,4)/2)],'+')
Daniel@0 80 title('Resonator Pole/Zero')
Daniel@0 81 drawnow;
Daniel@0 82 end
Daniel@0 83
Daniel@0 84 % Convert r-theta form, first into a list of roots, then a polynomial
Daniel@0 85 roots=exp(i*PreemphasisRTheta(:,2)).*PreemphasisRTheta(:,1);
Daniel@0 86 SeneffPreemphasis=real(poly([roots;conj(roots)]));
Daniel@0 87
Daniel@0 88 % Plot the preemphasis filter response, if desired
Daniel@0 89 if plotTests
Daniel@0 90 subplot(3,3,3);
Daniel@0 91 freqScale=(0:255)/256*8000;
Daniel@0 92 freqresp = FreqResp(SeneffPreemphasis,[1], freqScale, 16000);
Daniel@0 93 semilogx(freqScale,freqresp)
Daniel@0 94 title('Preemphasis Response');
Daniel@0 95 axis([100 10000 -60 20])
Daniel@0 96 drawnow;
Daniel@0 97 end
Daniel@0 98
Daniel@0 99 % Now figure out the second order sections that make up the main
Daniel@0 100 % filter bank cascade. We put the zeros into the numerator (b's)
Daniel@0 101 % and there are no poles. Just to keep things simpler, we adjust
Daniel@0 102 % the gain of each filter to keep it unity gain at DC.
Daniel@0 103 [channels,width] = size(FilterBankRTheta);
Daniel@0 104 roots=exp(i*FilterBankRTheta(:,2)).*FilterBankRTheta(:,1);
Daniel@0 105 SeneffFilterBank = zeros(channels,5);
Daniel@0 106 for j=1:channels
Daniel@0 107 SeneffFilterBank(j,1:3) = poly([roots(j) conj(roots(j))]);
Daniel@0 108 SeneffFilterBank(j,1:3) = SeneffFilterBank(j,1:3)/sum(SeneffFilterBank(j,1:3));
Daniel@0 109 end
Daniel@0 110
Daniel@0 111 % Plot the cascade zero responses, if desired.
Daniel@0 112 if plotTests
Daniel@0 113 subplot(3,3,4);
Daniel@0 114 y=soscascade([1 zeros(1,511)],SeneffFilterBank);
Daniel@0 115 freqresp=20*log10(abs(fft(y(1:5:40,:)')));
Daniel@0 116 freqScale=(0:511)/512*16000;
Daniel@0 117 semilogx(freqScale(1:256),freqresp(1:256,:))
Daniel@0 118 axis([100 10000 -150 0]);
Daniel@0 119 title('Cascade Response');
Daniel@0 120 drawnow;
Daniel@0 121 end
Daniel@0 122
Daniel@0 123 % Now figure out the resonating filters. Each of these resonators
Daniel@0 124 % is a double pole-zero pair.
Daniel@0 125 zlocs = FilterBankRTheta(:,5).*exp(i*FilterBankRTheta(:,4)/2);
Daniel@0 126 plocs = FilterBankRTheta(:,3).*exp(i*FilterBankRTheta(:,4));
Daniel@0 127 SeneffForward = zeros(5,channels);
Daniel@0 128 SeneffBackward = zeros(5,channels);
Daniel@0 129
Daniel@0 130 for j=1:channels
Daniel@0 131 SeneffForward(:,j) = real(poly([zlocs(j) conj(zlocs(j)) ...
Daniel@0 132 zlocs(j) conj(zlocs(j))]))';
Daniel@0 133 SeneffBackward(:,j) = real(poly([plocs(j) conj(plocs(j)) ...
Daniel@0 134 plocs(j) conj(plocs(j))]))';
Daniel@0 135 end
Daniel@0 136
Daniel@0 137 % Now plot the frequency response of just the resonating filters.
Daniel@0 138 % These are all bandpass filters.
Daniel@0 139 if plotTests
Daniel@0 140 subplot(3,3,5);
Daniel@0 141 impulse = [1 zeros(1,255)];
Daniel@0 142 y=zeros(256,channels);
Daniel@0 143 for j=1:40
Daniel@0 144 y(:,j) = filter(SeneffForward(:,j),SeneffBackward(:,j),impulse)';
Daniel@0 145 end
Daniel@0 146 freqresp=20*log10(abs(fft(y(:,1:5:40))));
Daniel@0 147 freqScale=(0:255)/256*16000;
Daniel@0 148 semilogx(freqScale(1:128),freqresp(1:128,:))
Daniel@0 149 axis([100 10000 -30 40]);
Daniel@0 150 title('Resonators Response')
Daniel@0 151 drawnow;
Daniel@0 152 end
Daniel@0 153
Daniel@0 154 % The plot below shows the overall response of the preemphasis filters
Daniel@0 155 % along with the just-designed cascade of zeros.
Daniel@0 156 if plotTests
Daniel@0 157 subplot(3,3,6);
Daniel@0 158 impulse = [1 zeros(1,511)];
Daniel@0 159 y=soscascade(filter(SeneffPreemphasis, [1], impulse), ...
Daniel@0 160 SeneffFilterBank);
Daniel@0 161 freqresp=20*log10(abs(fft(y(1:5:40,:)')));
Daniel@0 162 freqScale=(0:511)/512*16000;
Daniel@0 163 semilogx(freqScale(1:256),freqresp(1:256,:))
Daniel@0 164 axis([100 10000 -100 25]);
Daniel@0 165 title('Preemphasis+Cascade');
Daniel@0 166 drawnow;
Daniel@0 167 end
Daniel@0 168
Daniel@0 169 % Now we need to normalize the gain of each channel. We run an impulse
Daniel@0 170 % through the preemphasis filter, and then through the cascade of zeros.
Daniel@0 171 % Finally, we run it through each of the resonator filters.
Daniel@0 172 impulse = [1 zeros(1,255)];
Daniel@0 173 y=soscascade(filter(SeneffPreemphasis, [1], impulse), ...
Daniel@0 174 SeneffFilterBank);
Daniel@0 175 for j=1:channels
Daniel@0 176 y(j,:) = filter(SeneffForward(:,j),SeneffBackward(:,j),y(j,:));
Daniel@0 177 end
Daniel@0 178
Daniel@0 179 % Now we have impulse responses from each filter. We can find the FFT
Daniel@0 180 % and then find the gain peak. We divide each forward polynomial by the
Daniel@0 181 % maximum gain (to normalize) and then multiply by the desired low
Daniel@0 182 % frequency roll-off. The Bryant paper says that the last 24 channels
Daniel@0 183 % should be cut at 6dB per octave and that this occurs at 1600 Hz, but
Daniel@0 184 % it looks to me like the gain change happens at 3200 Hz.
Daniel@0 185 freqresp=abs(fft(y'));
Daniel@0 186 gain = ones(1,channels)./max(freqresp);
Daniel@0 187 cfs = FilterBankRTheta(:,4)/pi*fs/2;
Daniel@0 188 rolloff = min(cfs/1600,1);
Daniel@0 189
Daniel@0 190 for j=1:channels
Daniel@0 191 SeneffForward(:,j)=SeneffForward(:,j)*gain(j)*rolloff(j);
Daniel@0 192 end
Daniel@0 193
Daniel@0 194 % All Done. The figure below should match Figure 3 of Bryant's paper.
Daniel@0 195 if plotTests
Daniel@0 196 subplot(3,3,8);
Daniel@0 197 impulse = [1 zeros(1,511)];
Daniel@0 198 y=soscascade(filter(SeneffPreemphasis, [1], impulse), ...
Daniel@0 199 SeneffFilterBank);
Daniel@0 200 for j=1:channels
Daniel@0 201 y(j,:) = filter(SeneffForward(:,j),SeneffBackward(:,j),y(j,:));
Daniel@0 202 end
Daniel@0 203
Daniel@0 204 freqresp=20*log10(abs(fft(y(1:5:40,:)')));
Daniel@0 205 freqScale=(0:511)/512*16000;
Daniel@0 206 plot(freqScale(1:256),freqresp(1:256,:))
Daniel@0 207 axis([100 10000 -120 0]);
Daniel@0 208 title('Magnitude Response vs. Linear Frequency');
Daniel@0 209 drawnow;
Daniel@0 210 end
Daniel@0 211
Daniel@0 212
Daniel@0 213 function mag=FreqResp(b,a,f,fs)
Daniel@0 214 cf = exp(i*2*pi*f/fs);
Daniel@0 215 num = 0;
Daniel@0 216 for i=1:length(b)
Daniel@0 217 num = num + b(end-i+1)*cf.^i;
Daniel@0 218 end
Daniel@0 219
Daniel@0 220 denom = 0;
Daniel@0 221 for i=1:length(a)
Daniel@0 222 denom = denom + a(end-i+1)*cf.^i;
Daniel@0 223 end
Daniel@0 224 mag = 20*log10(abs(num./denom));