opensuze/modelisationanalysespectrale
2
0
Fork 0
Code Issues Pull requests Releases Wiki Activity

original commit

Browse source
This commit is contained in:
Raphaël Bolut 2019-10-12 23:41:54 +02:00
parent 8946bbd6e0
commit b537cca982
15 changed files with 158 additions and 0 deletions
Show stats Download patch file Download diff file Expand all files Collapse all files

BIN
rossignol/parametrique/fluteircam-dsp_AR.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 71 KiB

BIN
rossignol/parametrique/fluteircam-dsp_AR_full.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 110 KiB

BIN
rossignol/parametrique/fluteircam-dsp_fft.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 97 KiB

BIN
rossignol/parametrique/fluteircam-dsp_max_AR.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 22 KiB

BIN
rossignol/parametrique/fluteircam-dsp_max_fft.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 21 KiB

BIN
rossignol/parametrique/fluteircam-signal.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 36 KiB

57
rossignol/parametrique/mylevinsondurbin.m Normal file
View file

@ -0,0 +1,57 @@
%%% Algorithme de Levinson-Durbin pour la d\'etermination des param\`etres AR
%%%
%%% entr\'ees :
%%% - xx : signal
%%% - pp : ordre du mod\`ele AR (choisi de mani\`ere ind\'ependante)
%%% - fe : fr\'equence d'\'echantillonnage
%%%
%%% sorties :
%%% - aa : les param\`etres AR
%%% - sigma2 : variance du bruit
%%% - ref : coefficients de r\'eflexion
%%% - ff : fr\'equences auxquelles la dsp a \'et\'e calcul\'ee
%%% - mydsp : la dsp elle-m\^eme
%%%
%%% exemple : fe=32000;f0=440;xx=cos(2*pi*f0/fe*[1:1280]+2*pi*rand(1,1));mylevinsondurbin(xx,4,fe);
%%%
%%% S. Rossignol -- 2012
function [aa, sigma2, ref, ff, mydsp] = mylevinsondurbin (xx, pp, fe)
acf = xcorr(xx, pp+1, 'biased'); %% autocorr\'elation
acf(1:pp+1) = []; %% on enl\`eve la partie n\'egative
acf(1) = real(acf(1)); %% Levinson-Durbin requiert c(1)==conj(c(1))
ref = zeros(pp,1);
gg = -acf(2)/acf(1);
aa = [ gg ];
sigma2 = real( ( 1 - gg*conj(gg)) * acf(1) ); %% real : enl\`eve une \'eventuelle
%% partie imaginaire r\'esiduelle
ref(1) = gg;
for tt = 2 : pp
gg = -(acf(tt+1) + aa * acf(tt:-1:2)') / sigma2;
aa = [ aa + gg*conj(aa(tt-1:-1:1)), gg ];
sigma2 = sigma2 * ( 1 - real(gg*conj(gg)) );
ref(tt) = gg;
end;
aa = [1, aa];
%%% densit\'e spectrale de puissance
interm2=-j*2*pi/fe*[1:pp];
df=0.9765625; %%% la dsp est calcul\'ee tous les df Hz
ff=-fe/2:df:fe/2;
interm3=interm2'*ff;
interm=1.+aa(2:pp+1)*exp(interm3);
mydsp = sigma2./(interm.*conj(interm));
% figure(1);
% clf;
% grid on;
% hold on;
% plot(ff,mydsp,'linewidth',2);
% xlabel('frequency (in Hz)','fontsize',20);
% ylabel('magnitude','fontsize',20);
% hold off;
% drawnow;

BIN
rossignol/parametrique/myson-amp_dsp_AR.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 40 KiB

BIN
rossignol/parametrique/myson-amp_dsp_AR_full.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 24 KiB

BIN
rossignol/parametrique/myson-amp_dsp_FFT.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 59 KiB

BIN
rossignol/parametrique/myson-amp_dsp_FFT_full.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 43 KiB

BIN
rossignol/parametrique/myson-dsp_max_AR.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 34 KiB

BIN
rossignol/parametrique/myson-dsp_max_fft.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 31 KiB

BIN
rossignol/parametrique/myson-signal.png Normal file
View file

Binary file not shown.
Side by side

After

Width:  |  Height:  |  Size: 38 KiB

101
rossignol/parametrique/parametrique.m Normal file
View file

@ -0,0 +1,101 @@
clear;
close all;
% returns sampling frequency in Hz and data
[y,Fs] = audioread('myson.wav');
% Fs = sampling frequency, 32000 for fluteircam.wav
lenW = 0.04*Fs; % window of lenW samples, i.e. 40 ms
df=0.9765625; %%% la dsp est calcul\'ee tous les df Hz
ff=-Fs/2:df:Fs/2; % length 32769 for fluteircam.wav
ffsub = ff(1:11:end); % compression x11, length 2979
tt = (0:length(y)-1)/Fs;
ttsub = (lenW/2:lenW:length(y))/Fs;
dsps = zeros(length(ffsub), floor((length(y)-lenW+1)/lenW));
% dsp fft
T = 1/Fs; % Sampling period
L = lenW; % Length of signal
t = (0:L-1)*T; % Time vector
fftsp = zeros(L/2+1, floor((length(y)-lenW+1)/lenW));
fftspCpx = zeros(L/2+1, floor((length(y)-lenW+1)/lenW));
f = Fs*(0:(L/2))/L;
for i = 0:floor((length(y)-lenW+1)/lenW)
% compute dsp AR
[~, ~, ~, ~, mydsp] = mylevinsondurbin(y(lenW*i+1:lenW*(i+1))',200,Fs);
dsps(:,i+1) = mydsp(1:11:end)'; % compression x11, length 2979
% compute dsp fft
myfft = fft(y(lenW*i+1:lenW*(i+1)));
P2 = abs(myfft/L);
P1 = P2(1:L/2+1);
P1(2:end-1) = 2*P1(2:end-1);
fftsp(:,i+1) = P1;
end
% take only positive frequencies for dsp
ffsubp = ffsub(1,(length(ffsub)-1)/2+1:end);
dspsp = dsps((length(dsps)-1)/2+1:end,:);
% plot
figure()
plot(tt,y)
xlabel('temps (s)')
ylabel('amplitude (u.a.)')
title('signal fluteircam')
% figure()
% surf(ttsub,ffsub,dsps,'EdgeColor','None');
% xlabel('temps (s)')
% ylabel('fréquences (Hz)')
% zlabel('amplitudes (u.a.)')
% title('Full DSP AR signal fluteircam')
figure()
surf(ttsub,ffsubp,dspsp,'EdgeColor','None');
xlabel('temps (s)')
ylabel('fréquences (Hz)')
zlabel('amplitudes (u.a.)')
title('DSP AR signal fluteircam')
figure()
imagesc(ttsub,ffsubp,dspsp)
xlabel('temps (s)')
ylabel('fréquences (Hz)')
title('Amplitude DSP AR signal fluteircam')
figure()
surf(ttsub,f,fftsp,'EdgeColor','None');
xlabel('temps (s)')
ylabel('fréquences (Hz)')
zlabel('amplitudes (u.a.)')
title('DSP FFT signal fluteircam')
figure()
imagesc(ttsub,f,fftsp)
xlabel('temps (s)')
ylabel('fréquences (Hz)')
title('Amplitude DSP FFT signal fluteircam')
% take max amplitude frequency
[maxDspsp, maxIndDspsp] = max(dspsp);
maxFfsubp = ffsubp(maxIndDspsp);
figure
plot(ttsub,maxFfsubp)
xlabel('temps (s)')
ylabel('fréquences (Hz)')
title('Frequency max DSP AR signal fluteircam')
[maxFftsp, maxIndFftsp] = max(fftsp);
maxF = f(maxIndFftsp);
figure
plot(ttsub,maxF)
xlabel('temps (s)')
ylabel('fréquences (Hz)')
title('Frequency max DSP FFT signal fluteircam')