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view m-toolbox/classes/@matrix/fromCSD.m @ 0:f0afece42f48
Import.
author | Daniele Nicolodi <nicolodi@science.unitn.it> |
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date | Wed, 23 Nov 2011 19:22:13 +0100 |
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% FROMCSD Construct a matrix filter from cross-spectral density matrix %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FUNCTION: fromCSD % % DESCRIPTION: Construct matrix filter from cross-spectral density. Such a % filter can be used for multichannel noise generation in combination with % the MultiChannelNoise constructor of the matrix class. % % % CALL: a = fromCSD(a, pl) % % PARAMETER: pl: plist containing 'csd' % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function a = fromCSD(a, pli) VERSION = '$Id: fromCSD.m,v 1.8 2010/10/29 16:09:12 ingo Exp $'; % get AO info iobj = matrix.getInfo('matrix', 'From CSD'); % Set the method version string in the minfo object iobj.setMversion([VERSION '-->' iobj.mversion]); % Add default values pl = parse(pli, iobj.plists); % Get parameters and set params for fit csdm = find(pl, 'csd'); if isa(csdm,'matrix') % get elements out of the input matrix csdao = csdm.objs; else csdao = csdm; end fs = find(pl, 'fs'); target = lower(find(pl, 'targetobj')); % decide to perform s domain or z domain identification % if target is parfrac output a matrix of parfarc objs (s domain % identification) % if target is miir output a matrix of filterbank parallel miir objects % (z domain identification) usesym = lower(find(pl, 'UseSym')); if (fs == 0) && strcmpi(target,'miir') error('### Please provide a valid sampling frequency for CSD constructor.'); elseif isempty(fs) && strcmpi(target,'miir') error('### Please provide a valid sampling frequency for CSD constructor.'); end % get units for filters tgiunit = find(pl,'iunits'); tgounit = find(pl,'ounits'); params = struct(); params.Nmaxiter = find(pl, 'MaxIter'); params.minorder = find(pl, 'MinOrder'); params.maxorder = find(pl, 'MaxOrder'); params.spolesopt = find(pl, 'PoleType'); params.weightparam = find(pl, 'Weights'); % set the target output if strcmpi(target,'miir') params.TargetDomain = 'z'; elseif strcmpi(target,'parfrac') params.TargetDomain = 's'; else error('### Unknown option for ''targetobj''.'); end % Tolerance for MSE Value lrscond = find(pl, 'FITTOL'); % give an error for strange values of lrscond if lrscond<0 error('### Negative values for FITTOL are not allowed. ') end % handling data lrscond = -1*log10(lrscond); % give a warning for strange values of lrscond if lrscond<0 warning('You are searching for a MSE lower than %s', num2str(10^(-1*lrscond))) end params.lrscond = lrscond; % Tolerance for the MSE relative variation msevar = find(pl, 'MSEVARTOL'); % handling data msevar = -1*log10(msevar); % give a warning for strange values of msevar if msevar<0 warning('You are searching for MSE relative variation lower than %s', num2str(10^(-1*msevar))) end params.msevar = msevar; if isempty(params.msevar) params.ctp = 'chival'; else params.ctp = 'chivar'; end if(find(pl, 'plot')) params.plot = 1; else params.plot = 0; end params.fs = fs; params.dterm = 0; % it is better to fit without direct term % check if symbolic calculation is required if strcmpi(usesym,'on') params.usesym = 1; elseif strcmpi(usesym,'off') params.usesym = 0; else error('### Unknown option for ''UseSym''.'); end % extracting csd if numel(csdao)==1 % one dimensional psd csd = csdao.y; freq = csdao.x; dim = 'one'; else % multichannel system dim = 'multi'; [nn,mm] = size(csdao); if nn~=mm error('### CSD Matrix must be square. ') end freq = csdao.index(1).x; for ii = 1:nn for jj = 1:nn tcsd = csdao.index(ii,jj).y; % willing to work with columns [aa,bb] = size(tcsd); if aa<bb tcsd = tcsd.'; end csd(ii,jj,:) = tcsd; end end end % call csd2tf % ostruct is a struct array whose fields contain the residues and poles % of estimated TFs. Since the fit is porformed on the columns of the TF % matrix, each element of the array contains the residues and poles % corresponding to the functions on the given column of the TF matrix. %ostruct = utils.math.csd2tf(csd,freq,params); ostruct = utils.math.csd2tf2(csd,freq,params); % the filter for each channel is implemented by the rows of the TF matrix switch dim case 'one' switch target case 'miir' % --- filter --- res = ostruct.res; poles = ostruct.poles; % construct a struct array of miir filters vectors pfilts(numel(res),1) = miir; for kk=1:numel(res) ft = miir(res(kk), [ 1 -poles(kk)], fs); ft.setIunits(unit(tgiunit)); ft.setOunits(unit(tgounit)); pfilts(kk,1) = ft; clear ft end filt = filterbank(pfilts,'parallel'); a = matrix(filt); % Add history a.addHistory(iobj, pl, [], [csdao(:).hist]); case 'parfrac' res = ostruct.res; poles = ostruct.poles; fbk = parfrac(res,poles,0); fbk.setIunits(unit(tgiunit)); fbk.setOunits(unit(tgounit)); a = matrix(fbk); % Add history a.addHistory(iobj, pl, [], [csdm(:).hist]); end case 'multi' switch target case 'miir' % init filters array %fbk(nn*nn,1) = filterbank; %fbk = filterbank.newarray([nn nn]); for zz=1:nn*nn % run over system dimension % --- get column filter coefficients --- % each column of mres\mpoles are the coefficients of a given filter clear res poles res = ostruct(zz).res; poles = ostruct(zz).poles; % construct a struct array of miir filters vectors %ft(numel(res),1) = miir; for kk=1:numel(res) ft(kk,1) = miir(res(kk), [1 -poles(kk)], fs); ft(kk,1).setIunits(unit(tgiunit)); ft(kk,1).setOunits(unit(tgounit)); end fbk(zz,1) = filterbank(ft,'parallel'); clear ft end mfbk = reshape(fbk,nn,nn); a = matrix(mfbk); % % overide default name % if strcmpi(pl.find('name'), 'None') % pl.pset('name', sprintf('fromCSD(%s)', csdao.name)); % end % % overide default description % if isempty(pl.find('description')) % pl.pset('description', csdao.description); % end % Add history a.addHistory(iobj, pl, [], [csdao(:).hist]); case 'parfrac' % init filters array %fbk(nn*nn,1) = parfrac; for zz=1:nn*nn % run over system dimension % --- get column filter coefficients --- % each column of mres\mpoles are the coefficients of a given filter clear res poles res = ostruct(zz).res; poles = ostruct(zz).poles; fbk(zz,1) = parfrac(res,poles,0); fbk(zz,1).setIunits(unit(tgiunit)); fbk(zz,1).setOunits(unit(tgounit)); end mfbk = reshape(fbk,nn,nn); a = matrix(mfbk); % % overide default name % if strcmpi(pl.find('name'), 'None') % pl.pset('name', sprintf('fromCSD(%s)', csdao.name)); % end % % overide default description % if isempty(pl.find('description')) % pl.pset('description', csdao.description); % end % Add history a.addHistory(iobj, pl, [], [csdao(:).hist]); end end % Set properties from the plist warning('off', utils.const.warnings.METHOD_NOT_FOUND); % remove parameters we already used pl_set = copy(pl,1); if pl_set.isparam('csd') pl_set.remove('csd'); end if pl_set.isparam('fs') pl_set.remove('fs'); end if pl_set.isparam('targetobj') pl_set.remove('targetobj'); end if pl_set.isparam('UseSym') pl_set.remove('UseSym'); end if pl_set.isparam('iunits') pl_set.remove('iunits'); end if pl_set.isparam('ounits') pl_set.remove('ounits'); end if pl_set.isparam('MaxIter') pl_set.remove('MaxIter'); end if pl_set.isparam('MinOrder') pl_set.remove('MinOrder'); end if pl_set.isparam('MaxOrder') pl_set.remove('MaxOrder'); end if pl_set.isparam('PoleType') pl_set.remove('PoleType'); end if pl_set.isparam('Weights') pl_set.remove('Weights'); end if pl_set.isparam('FITTOL') pl_set.remove('FITTOL'); end if pl_set.isparam('MSEVARTOL') pl_set.remove('MSEVARTOL'); end if pl_set.isparam('plot') pl_set.remove('plot'); end a.setProperties(pl_set); warning('on', utils.const.warnings.METHOD_NOT_FOUND); end