Mercurial > hg > ltpda
view m-toolbox/classes/@ao/mlpsd_mex.m @ 11:9174aadb93a5 database-connection-manager
Add LTPDA Repository utility functions into utils.repository
author | Daniele Nicolodi <nicolodi@science.unitn.it> |
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date | Mon, 05 Dec 2011 16:20:06 +0100 |
parents | f0afece42f48 |
children |
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% MLPSD_MEX calls the ltpda_dft.mex to compute the DFT part of the LPSD algorithm %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DESCRIPTION: MLPSD_MEX calls the ltpda_dft.mex to compute the DFT part of the % LPSD algorithm % % CALL: [S,Sxx,ENBW] = mlpsd_mex(x,f,r,m,L,fs,win,order,olap) % % VERSION: $Id: mlpsd_mex.m,v 1.13 2011/05/22 22:22:50 mauro Exp $ % % HISTORY: 19-05-2007 M Hewitson % Creation % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function varargout = mlpsd_mex(varargin) import utils.const.* utils.helper.msg(msg.PROC1, 'using ltpda_dft.mex to compute core DFT'); % Get inputs x = varargin{1}; f = varargin{2}; r = varargin{3}; m = varargin{4}; L = varargin{5}; fs = varargin{6}; win = varargin{7}; order = varargin{8}; olap = varargin{9}; Lmin = varargin{10}; twopi = 2.0*pi; nf = length(f); Sxx = zeros(nf,1); S = zeros(nf,1); ENBW = zeros(nf,1); devxx = zeros(nf,1); dev = zeros(nf,1); disp_each = round(nf/100)*10; winType = win.type; winPsll = win.psll; minReached = 0; for jj = 1:nf if mod(jj, disp_each) == 0 || jj == 1 || jj == nf utils.helper.msg(msg.PROC1, 'computing frequency %04d of %d: %f Hz', jj, nf, f(jj)); end % compute DFT exponent and window l = L(jj); % Check if we need to update the window values % - once we reach Lmin, the window values don't change. if ~minReached switch lower(winType) case 'kaiser' win = specwin(winType, l, winPsll); otherwise win = specwin(winType, l); end if l == Lmin minReached = 1; end end p = 1i * twopi * m(jj)/l.*(0:l-1); C = win.win .* exp(p); % Core DFT part in C-mex file [A, B,nsegs] = ltpda_dft(x, l, C, olap, order); if mod(jj, disp_each) == 0 || jj == 1 || jj == nf utils.helper.msg(msg.PROC2, 'averaged %d segments', nsegs); end A2ns = 2.0*A; B2ns = 4.0*B/nsegs; S1 = win.ws; S12 = S1*S1; S2 = win.ws2; ENBW(jj) = fs*S2/S12; % scale asd/psd Sxx(jj) = A2ns/fs/S2; S(jj) = A2ns/S12; % scale sqrt(variance) devxx(jj) = sqrt(B2ns/fs^2/S2^2); dev(jj) = sqrt(B2ns/S12^2); end varargout{1} = S; varargout{2} = Sxx; varargout{3} = dev; varargout{4} = devxx; varargout{5} = ENBW; end