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author | Daniele Nicolodi <nicolodi@science.unitn.it> |
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date | Mon, 05 Dec 2011 16:20:06 +0100 |
parents | f0afece42f48 |
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%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % TEST matrix/MultiChannelNoise % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % HISTORY: 23-04-2009 L Ferraioli % Creation %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %% VERSION '$Id: test_matrix_fromCSD.m,v 1.3 2009/04/23 16:03:55 luigi Exp $'; %% Loading spectra fs = 10; f = [logspace(-6,log10(fs/2),2000)]'; % currPath = cd; % cd MDC1 % assuming to start from ..\ltpda\software\m-toolbox\test % [TF,CSD] = mdc1_tf_models(plist('f',f,'fs',fs)); % cd(currPath) % get noise psd shapes % parameters names parnames = {'DH','S11','S1D','SD1','SDD','Dh1','Dh2','w1','w2',... 'TH','Th1','Th2'}; % nominal params values parvalues = {1,1,0,-1e-4,1,1,1,-1.3e-6,-2.0e-6,0.35,0.25,0.28}; % Noise model Ns = matrix(plist('built-in','mdc3_ifo2ifo_noise')); % evalueat model [rw,cl]=size(Ns.objs); for ii=1:rw for jj=1:cl Ns.objs(ii,jj).setParams(parnames,parvalues); Ns.objs(ii,jj).setXvals(f); CSD(ii,jj)=eval(Ns.objs(ii,jj)); if ii==jj CSD(ii,jj)= abs(CSD(ii,jj)); end end end %% Plot plpl = plist('Linecolors', {'k', 'r', 'b'},... 'LineStyles', {'-', '--', ':'},... 'LineWidths', {3, 3, 3},... 'Legends', {'S_{o_1 o_1}', 'S_{o_1 o_\Delta}', 'S_{o_\Delta o_\Delta}'}); % iplot(CSD(1,1),CSD(1,2),CSD(2,1),CSD(2,2)) iplot(CSD(1,1),CSD(1,2),CSD(2,2),plpl) %% %-------------------------------------------------------------------------- % 2 Dimensional Noisegen Filter %-------------------------------------------------------------------------- %% 2 dim noisegen filter in z domain - symbolic precision All pass % plist for noise generation plns = plist(... 'csd', CSD, ... 'targetobj', 'miir', ... 'fs', fs, ... 'MaxIter', 70, ... 'PoleType', 3, ... 'MinOrder', 25, ... 'MaxOrder', 55, ... 'Weights', 2, ... 'Plot', false,... 'MSEVARTOL', 1e-1,... 'FITTOL', 1e-4,... 'UseSym', 'on',... 'iunits', 'm',... 'ounits', 'm'); na = matrix(plns); %% Check response of CSD na11 = resp(na.objs(1,1).filters,plist('f',f,'bank','parallel')); na12 = resp(na.objs(1,2).filters,plist('f',f,'bank','parallel')); na21 = resp(na.objs(2,1).filters,plist('f',f,'bank','parallel')); na22 = resp(na.objs(2,2).filters,plist('f',f,'bank','parallel')); mna = matrix([na11 na12;na21 na22]); ECSD = mna*conj(transpose(mna)); for kk = 1:numel(CSD) CSD(kk).setYunits((unit('m')^2)*(unit('Hz')^-1)); CSD(kk).setXunits(unit('Hz')); ECSD.objs(kk).setYunits((unit('m')^2)*(unit('Hz')^-1)); ECSD.objs(kk).setXunits(unit('Hz')); end % calculate cross-coherence COH = CSD(1,2)./sqrt(CSD(1,1).*CSD(2,2)); COH.simplifyYunits; RCOH = real(COH); ICOH = imag(COH); ECOH = ECSD.objs(1,2)./sqrt(ECSD.objs(1,1).*ECSD.objs(2,2)); ECOH.simplifyYunits; RECOH = real(ECOH); IECOH = imag(ECOH); % set plist for plotting plpl = plist('Linecolors', {'k', 'r', 'b'},... 'LineStyles', {'-', '--', ':'},... 'LineWidths', {3, 3, 3},... 'Legends', {'Model', 'Fit', 'Residuals'}); iplot(CSD(1,1),ECSD.objs(1,1),abs(CSD(1,1)-ECSD.objs(1,1)),plpl) iplot(CSD(2,2),ECSD.objs(2,2),abs(CSD(2,2)-ECSD.objs(2,2)),plpl) plpl = plist('Linecolors', {'k', 'r', 'b'},... 'LineStyles', {'-', '--', ':'},... 'LineWidths', {3, 3, 3},... 'Legends', {'Model', 'Fit', 'Residuals'},... 'Yscales', {'All', 'lin'},... 'Ylabels', {'All', 'Re(coh)'}); iplot(RCOH,RECOH,abs(RCOH-RECOH),plpl) plpl = plist('Linecolors', {'k', 'r', 'b'},... 'LineStyles', {'-', '--', ':'},... 'LineWidths', {3, 3, 3},... 'Legends', {'Model', 'Fit', 'Residuals'},... 'Yscales', {'All', 'lin'},... 'Ylabels', {'All', 'Im(coh)'}); iplot(ICOH,IECOH,abs(ICOH-IECOH),plpl) %% Check response of Filters % na11 = resp(na.objs(1,1).filters,plist('f',f,'bank','parallel')); % na12 = resp(na.objs(1,2).filters,plist('f',f,'bank','parallel')); % na21 = resp(na.objs(2,1).filters,plist('f',f,'bank','parallel')); % na22 = resp(na.objs(2,2).filters,plist('f',f,'bank','parallel')); % iplot(TF(1,1),na11,abs(TF(1,1) - na11)) % iplot(TF(1,2),na12,abs(TF(1,2) - na12)) % iplot(TF(2,1),na21,abs(TF(2,1) - na21)) % iplot(TF(2,2),na22,abs(TF(2,2) - na22)) iplot(na11,na12,na21,na22) %% %-------------------------------------------------------------------------- % 2 Dimensional Noise Generation %-------------------------------------------------------------------------- nsecs = 3e5; plng = plist(... 'model', na,... 'Nsecs', nsecs,... 'fs', fs,... 'yunits', 'm'); no = matrix(plng); %% Check psd no1 = no.objs(1); no2 = no.objs(2); no1xx = no1.psd; no2xx = no2.psd; iplot(no1xx,csd11,no2xx,csd22) %% Check cross-coherence no1 = no.objs(1); no2 = no.objs(2); nfft = 6e4; no12xx = cpsd(no1,no2,plist('nfft',nfft)); no1xx = no1.psd(plist('nfft',nfft)); no2xx = no2.psd(plist('nfft',nfft)); %% ecoh = no12xx./(sqrt(no1xx.*no2xx)); recoh = real(ecoh); iecoh = imag(ecoh); iplot(recoh,RECOH,plist('Yscales',{'All','lin'})) iplot(iecoh,IECOH,plist('Yscales',{'All','lin'})) %% Get averaged noise spectral curves N = 500; nsecs = 3e5; nfft = 6e4; Mnxx1 = 0; Mn2xx1 = 0; Mnxx2 = 0; Mn2xx2 = 0; Mnxy1 = 0; Mn2xy1 = 0; Mnxy2 = 0; Mn2xy2 = 0; tic for ii = 1:N fprintf('===== iter %s =====\n',num2str(ii)) % noise generation plng = plist(... 'model', na,... 'Nsecs', nsecs,... 'fs', fs,... 'yunits', 'm'); no = matrix(plng); % periodogram calculation no1 = no.objs(1); no2 = no.objs(2); no1xx = no1.psd; no2xx = no2.psd; f1 = no1xx.x; % running average and variance for periodogram if ii == 1 Mnxx1 = no1xx.y; Mnxx2 = no2xx.y; else % Qxx1 = no1xx.y - Mnxx1; Mnxx1 = Mnxx1 + (no1xx.y - Mnxx1)./ii; Mn2xx1 = Mn2xx1 + (no1xx.y - Mnxx1).*(no1xx.y - Mnxx1); % Qxx2 = no2xx.y - Mnxx2; Mnxx2 = Mnxx2 + (no2xx.y - Mnxx2)./ii; Mn2xx2 = Mn2xx2 + (no2xx.y - Mnxx2).*(no2xx.y - Mnxx2); end clear no1xx no2xx % cross coherence calculation no12xx = cpsd(no1,no2,plist('nfft',nfft)); no1xx2 = no1.psd(plist('nfft',nfft)); no2xx2 = no2.psd(plist('nfft',nfft)); f2 = no1xx2.x; ecoh = (no12xx.y)./(sqrt((no1xx2.y).*(no2xx2.y))); recoh = real(ecoh); iecoh = imag(ecoh); clear no12xx no1xx2 no2xx2 % running average and variance for cross coherence if ii == 1 Mnxy1 = recoh; Mnxy2 = iecoh; else % Qxy1 = recoh - Mnxy1; Mnxy1 = Mnxy1 + (recoh - Mnxy1)./ii; Mn2xy1 = Mn2xy1 + (recoh - Mnxy1).*(recoh - Mnxy1); % Qxy2 = iecoh - Mnxy2; Mnxy2 = Mnxy2 + (iecoh - Mnxy2)./ii; Mn2xy2 = Mn2xy2 + (iecoh - Mnxy2).*(iecoh - Mnxy2); end end toc % get mean and variance for psd 1 Sxx1 = Mnxx1; % mean if N == 1 Svxx1 = Sxx1; else Svxx1 = (Mn2xx1/(N-1))/N; % variance end % get mean and variance for psd 2 Sxx2 = Mnxx2; % mean if N == 1 Svxx2 = Sxx2; else Svxx2 = (Mn2xx2/(N-1))/N; % variance end % get mean and variance for real part of cross coherence Sxy1 = Mnxy1; % mean if N == 1 Svxy1 = Sxy1; else Svxy1 = (Mn2xy1/(N-1))/N; % variance end % get mean and variance for imaginary part of cross coherence Sxy2 = Mnxy2; % mean if N == 1 Svxy2 = Sxy2; else Svxy2 = (Mn2xy2/(N-1))/N; % variance end % save results save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxx1.mat','Sxx1') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxx1.mat','Svxx1') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxx2.mat','Sxx2') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxx2.mat','Svxx2') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxy1.mat','Sxy1') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxy1.mat','Svxy1') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxy2.mat','Sxy2') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxy2.mat','Svxy2') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\f1.mat','f1') save('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\f2.mat','f2') save(na,'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\na.mat') %% Load saved data load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxx1.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxx1.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxx2.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxx2.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxy1.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxy1.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxy2.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxy2.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\f1.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\f2.mat' %% Plot spectra figure() p22 = loglog(f1(1:end-1),Sxx1(1:end-1) + sqrt(Svxx1(1:end-1)),'b','LineWidth',3); hold on grid on p23 = loglog(f1(1:end-1),Sxx1(1:end-1) - sqrt(Svxx1(1:end-1)),'b','LineWidth',3); p21 = loglog(f1(1:end-1),Sxx1(1:end-1),'r','LineWidth',3); p11 = loglog(ECSD.objs(1,1).x,ECSD.objs(1,1).y,'k','LineWidth',3); xlabel('Frequency [Hz]','fontsize',18) ylabel('amplitude [m^2 Hz^{-1}]','fontsize',18) legend([p11(1) p21(1) p22(1)],'Fit Model', 'Data', 'Error \pm \sigma') figure() p22 = loglog(f1(1:end-1),Sxx2(1:end-1) + sqrt(Svxx2(1:end-1)),'b','LineWidth',3); hold on grid on p23 = loglog(f1(1:end-1),Sxx2(1:end-1) - sqrt(Svxx2(1:end-1)),'b','LineWidth',3); p21 = loglog(f1(1:end-1),Sxx2(1:end-1),'r','LineWidth',3); p11 = loglog(ECSD.objs(2,2).x,ECSD.objs(2,2).y,'k','LineWidth',3); xlabel('Frequency [Hz]','fontsize',18) ylabel('amplitude [m^2 Hz^{-1}]','fontsize',18) legend([p11(1) p21(1) p22(1)],'Fit Model', 'Data', 'Error \pm \sigma') %% Plot coherence figure() p22 = semilogx(f2,Sxy1 + sqrt(Svxy1),'b','LineWidth',3); hold on grid on p23 = semilogx(f2,Sxy1 - sqrt(Svxy1),'b','LineWidth',3); p21 = semilogx(f2,Sxy1,'r','LineWidth',3); p11 = semilogx(RECOH.x,RECOH.y,'k','LineWidth',3); xlabel('Frequency [Hz]','fontsize',18) ylabel('Re(coh) []','fontsize',18) legend([p11(1) p21(1) p22(1)],'Fit Model', 'Data', 'Error \pm \sigma') figure() p22 = semilogx(f2,Sxy2 + sqrt(Svxy2),'b','LineWidth',3); hold on grid on p23 = semilogx(f2,Sxy2 - sqrt(Svxy2),'b','LineWidth',3); p21 = semilogx(f2,Sxy2,'r','LineWidth',3); p11 = semilogx(IECOH.x,IECOH.y,'k','LineWidth',3); xlabel('Frequency [Hz]','fontsize',18) ylabel('Im(coh) []','fontsize',18) legend([p11(1) p21(1) p22(1)],'Fit Model', 'Data', 'Error \pm \sigma') %% Check response of CSD currPath = cd; cd MDC1 % assuming to start from ..\ltpda\software\m-toolbox\test [TF,CSD] = mdc1_tf_models(plist('f',f1,'fs',fs)); cd(currPath) na11 = resp(na.objs(1,1).filters,plist('f',f1,'bank','parallel')); na12 = resp(na.objs(1,2).filters,plist('f',f1,'bank','parallel')); na21 = resp(na.objs(2,1).filters,plist('f',f1,'bank','parallel')); na22 = resp(na.objs(2,2).filters,plist('f',f1,'bank','parallel')); mna = matrix([na11 na12;na21 na22]); ECSD = mna*conj(transpose(mna)); for kk = 1:numel(CSD) CSD(kk).setYunits((unit('m')^2)*(unit('Hz')^-1)); CSD(kk).setXunits(unit('Hz')); ECSD.objs(kk).setYunits((unit('m')^2)*(unit('Hz')^-1)); ECSD.objs(kk).setXunits(unit('Hz')); end plpl = plist('Linecolors', {'k', 'r', 'b'},... 'LineStyles', {'-', '--', ':'},... 'LineWidths', {3, 3, 3},... 'Legends', {'Model', 'Fit', 'Residuals'}); iplot(CSD(1,1),ECSD.objs(1,1),abs(CSD(1,1)-ECSD.objs(1,1)),plpl) iplot(CSD(2,2),ECSD.objs(2,2),abs(CSD(2,2)-ECSD.objs(2,2)),plpl) %% get expected response + window % we should considere that the window has a spectral response that can add % some systematics inside our spectral estimations. Since the window is a % product in time domain with the time series, that it corresponds to a % convolution in frequency domain. We can ifft the frequency response of % the filters, multiply in time domain for the window and then come back to % freq domain by fft. na = matrix('C:\Users\Luigi\Lavori\ltp_noisegen\matlab\na.mat'); %% % filter responses fs = 10; nsecs = 3e5; nfft = nsecs.*fs; ff1 = (0:floor(nfft/2)).*fs./nfft; rsp11 = resp(na.objs(1,1).filters,plist('f',ff1,'bank','parallel')); rsp11 = rsp11.y; % rsp11 = [rsp11(1:end-1);flipud(conj(rsp11(2:end)))]; rsp12 = resp(na.objs(1,2).filters,plist('f',ff1,'bank','parallel')); rsp12 = rsp12.y; % rsp12 = [rsp12(1:end-1);flipud(conj(rsp12(2:end)))]; rsp21 = resp(na.objs(2,1).filters,plist('f',ff1,'bank','parallel')); rsp21 = rsp21.y; % rsp21 = [rsp21(1:end-1);flipud(conj(rsp21(2:end)))]; rsp22 = resp(na.objs(2,2).filters,plist('f',ff1,'bank','parallel')); rsp22 = rsp22.y; % rsp22 = [rsp22(1:end-1);flipud(conj(rsp22(2:end)))]; clear na % psd calc (npsd should contain nfft samples) npsd11 = rsp11.*conj(rsp11) + rsp12.*conj(rsp12); % npsd11 = [npsd11;flipud(npsd11(2:end-1))]; npsd22 = rsp21.*conj(rsp21) + rsp22.*conj(rsp22); % npsd22 = [npsd22;flipud(npsd22(2:end-1))]; %% % get window frequency response % BH92 in frequency domain W = BH92(2.*pi.*ff1./fs,nfft); W = W./max(abs(W)); W = W.*conj(W); %% ifft dello spettro % npsd11 = [npsd11;flipud(npsd11(2:end-1))]./2; % npsd22 = [npsd22;flipud(npsd22(2:end-1))]./2; % g11 = ifft(npsd11); % g22 = ifft(npsd22); W = blackmanharris(nfft); if size(W,2)>1 W = W.'; end W = W.^2; W = ifftshift(W); WS11 = fft(W.*g11); WS22 = fft(W.*g22); WS11 = 2.*WS11(1:numel(ff1)); WS22 = 2.*WS22(1:numel(ff1)); %% get convolution % WS11 = conv(W,npsd11); % WS11 = WS11(1:numel(ff1)); %% Plot spectra load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxx1.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxx1.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Sxx2.mat' load 'C:\Users\Luigi\Lavori\ltp_noisegen\matlab\Svxx2.mat' %% figure() p22 = loglog(ff1(1:end-1),Sxx1(1:end-1) + sqrt(Svxx1(1:end-1)),'b','LineWidth',3); hold on grid on p23 = loglog(ff1(1:end-1),Sxx1(1:end-1) - sqrt(Svxx1(1:end-1)),'b','LineWidth',3); p21 = loglog(ff1(1:end-1),Sxx1(1:end-1),'r','LineWidth',3); p11 = loglog(ff1(1:end),WS11(1:end),'k','LineWidth',3); xlabel('Frequency [Hz]','fontsize',18) ylabel('amplitude [m^2 Hz^{-1}]','fontsize',18) legend([p11(1) p21(1) p22(1)],'Fit Model', 'Data', 'Error \pm \sigma') %% figure() p22 = loglog(ff1(1:end-1),Sxx2(1:end-1) + sqrt(Svxx2(1:end-1)),'b','LineWidth',3); hold on grid on p23 = loglog(ff1(1:end-1),Sxx2(1:end-1) - sqrt(Svxx2(1:end-1)),'b','LineWidth',3); p21 = loglog(ff1(1:end-1),Sxx2(1:end-1),'r','LineWidth',3); p11 = loglog(ff1(1:end-1),WS22(1:end-1),'k','LineWidth',3); xlabel('Frequency [Hz]','fontsize',18) ylabel('amplitude [m^2 Hz^{-1}]','fontsize',18) legend([p11(1) p21(1) p22(1)],'Fit Model', 'Data', 'Error \pm \sigma') %% get statistics Sn11 = (npsd11(14:end-1)-Sxx1(14:end-1))./npsd11(14:end-1); Sn11 = ao(cdata(Sn11)); Sn22 = (npsd22(14:end-1)-Sxx2(14:end-1))./npsd22(14:end-1); Sn22 = ao(cdata(Sn22)); % get equivalent normal distribution and histogram hpl1 = plist('N', 50); hpl2 = plist('N', 200); dS11h = hist(Sn11,hpl1); dS11h = dS11h./max(dS11h); dS11n = normdist(Sn11,hpl2); dS11n = dS11n./max(dS11n); dS22h = hist(Sn22,hpl1); dS22h = dS22h./max(dS22h); dS22n = normdist(Sn22,hpl2); dS22n = dS22n./max(dS22n); %% check iplot(dS11h,dS11n) iplot(dS22h,dS22n) %% Plot results of the statistics analysis figure() p1 = bar(dS11h.x,dS11h.y,'b'); hold on grid on p2 = plot(dS11n.x,dS11n.y,'r','LineWidth',3); xlabel('Normalized Deviation [\Deltax / x]','fontsize',18) ylabel('Normalized Counts','fontsize',18) legend([p1(1) p2(1)],'Histogram', 'Equivalent Norm. Distr.') figure() p1 = bar(dS22h.x,dS22h.y,'b'); hold on grid on p2 = plot(dS22n.x,dS22n.y,'r','LineWidth',3); xlabel('Normalized Deviation [\Deltax / x]','fontsize',18) ylabel('Normalized Counts','fontsize',18) legend([p1(1) p2(1)],'Histogram', 'Equivalent Norm. Distr.') %% m1 = mean(Sn11.y); m2 = mean(Sn22.y); s1 = std(Sn11.y); s2 = std(Sn22.y); %% nfft = 1e2; fs = 10; frq = linspace(0,pi,10000); % D=DirichletKernel(frq,nfft); % D=D./max(D); % figure; % plot(frq,20.*log10(D)) % grid on W=BH92(frq,nfft); % W=W./max(W); figure; plot(frq./pi,20.*log10(W)) grid on