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Update ao_model_retrieve_in_timespan
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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% WELCHPARSE Parser for the PWELCH & SPECTROGRAM functions % % Outputs: % X - First input signal (used when esttype = MS & PSD) % M - An integer containing the length of the data to be segmented % isreal_x - Boolean for input complexity % Y - Second input signal (used when esttype = CPSD, TFE, MSCOHERE) % Ly - Length of second input signal (used when esttype = CPSD, TFE, MSCOHERE) % WIN - A scalar or vector containing the length of the window or the % window respectively (Note that the length of the window determines % the length of the segments) % WINNAME - String with the window name. % WINPARAM - Window parameter. % NOVERLAP - An integer containing the number of samples to overlap (may % be empty) % K - Number of segments % OPTIONS - A structure with the following fields: % OPTIONS.nfft - number of freq. points at which the psd is estimated % OPTIONS.Fs - sampling freq. if any % OPTIONS.range - 'onesided' or 'twosided' psd % % Direct copy from MATLAB % % M Hewitson 08-05-08 % % $Id: welchparse.m,v 1.3 2010/07/23 14:53:40 mauro Exp $ % % Author(s): P. Costa % Copyright 1988-2006 The MathWorks, Inc. % $Revision: 1.3 $ $Date: 2010/07/23 14:53:40 $ function [x,M,isreal_x,y,Ly,win,winName,winParam,noverlap,k,L,options] = ... welchparse(x,esttype,varargin) % Parse input arguments. [x,M,isreal_x,y,Ly,win,winName,winParam,noverlap,opts,errid,errmsg] = ... parse_inputs(x,esttype,varargin{:}); if ~isempty(errmsg), error(errid,errmsg); end % Obtain the necessary information to segment x and y. [L,noverlap,win,errid,errmsg] = segment_info(M,win,noverlap); if ~isempty(errmsg), error(errid,errmsg); end % Parse optional args nfft, fs, and spectrumType. [options,msg] = welch_options(isreal_x,L,opts{:}); if ~isempty(msg), error(generatemsgid('InvalidParam'),msg); end % Compute the number of segments k = (M-noverlap)./(L-noverlap); % Uncomment the following line to produce a warning each time the data % segmentation does not produce an integer number of segements. %if fix(k) ~= k, % warning(generatemsgid('MustBeInteger'),'The number of segments is not an integer, truncating data.'); %end k = fix(k); end %----------------------------------------------------------------------------------------------- function [x,Lx,isreal_x,y,Ly,win,winName,winParam,noverlap,opts,errid,errmsg] = ... parse_inputs(x,esttype,varargin) % Parse the inputs to the welch function. % Assign defaults in case of early return. isreal_x = 1; y = []; Ly = 0; is2sig = false; win = []; winName = 'User Defined'; winParam = ''; noverlap = []; opts = {}; errid = ''; errmsg = ''; % Determine if one or two signal vectors was specified. Lx = length(x); if iscell(x), if Lx > 1, % Cell array. y = x{2}; is2sig = true; end x = x{1}; Lx = length(x); else if ~any(strcmpi(esttype,{'psd','ms'})), errid = generatemsgid('invalidSignalVectors'); errmsg = 'You must specify a cell array with two signal vectors to estimate either the cross power spectral density or the transfer function.'; return; end end x = x(:); isreal_x = isreal(x); % Parse 2nd input signal vector. if is2sig, y = y(:); isreal_x = isreal(y) && isreal_x; Ly = length(y); if Ly ~= Lx, errid = generatemsgid('invalidSignalVectors'); errmsg = 'The length of the two input vectors must be equal to calculate the cross spectral density.'; return; end end % Parse window and overlap, and cache remaining inputs. lenargin = length(varargin); if lenargin >= 1, win = varargin{1}; if lenargin >= 2, noverlap = varargin{2}; % Cache optional args nfft, fs, and spectrumType. if lenargin >= 3, opts = varargin(3:end); end end end if isempty(win) | isscalar(win), winName = 'hamming'; winParam = 'symmetric'; end end %----------------------------------------------------------------------------------------------- %SEGMENT_INFO Determine the information necessary to segment the input data. % % Inputs: % M - An integer containing the length of the data to be segmented % WIN - A scalar or vector containing the length of the window or the window respectively % (Note that the length of the window determines the length of the segments) % NOVERLAP - An integer containing the number of samples to overlap (may be empty) % % Outputs: % L - An integer containing the length of the segments % NOVERLAP - An integer containing the number of samples to overlap % WIN - A vector containing the window to be applied to each section % ERRID - A string containing possible error identifier % ERRMSG - A string containing possible error messages % % % The key to this function is the following equation: % % K = (M-NOVERLAP)/(L-NOVERLAP) % % where % % K - Number of segments % M - Length of the input data X % NOVERLAP - Desired overlap % L - Length of the segments % % The segmentation of X is based on the fact that we always know M and two of the set % {K,NOVERLAP,L}, hence determining the unknown quantity is trivial from the above % formula. function [L,noverlap,win,errid,errmsg] = segment_info(M,win,noverlap) % Initialize outputs L = []; errid = ''; errmsg = ''; % Check that noverlap is a scalar if any(size(noverlap) > 1), errid = generatemsgid('invalidNoverlap'); errmsg = 'You must specify an integer number of samples to overlap.'; return; end if isempty(win), % Use 8 sections, determine their length if isempty(noverlap), % Use 50% overlap L = fix(M./4.5); noverlap = fix(0.5.*L); else L = fix((M+7.*noverlap)./8); end % Use a default window win = hamming(L); else % Determine the window and its length (equal to the length of the segments) if ~any(size(win) <= 1) | ischar(win), errid = generatemsgid('invalidWindow'); errmsg = 'The WINDOW argument must be a vector or a scalar.'; return elseif length(win) > 1, % WIN is a vector L = length(win); elseif length(win) == 1, L = win; win = hamming(win); end if isempty(noverlap), % Use 50% overlap noverlap = fix(0.5.*L); end end % Do some argument validation if L > M, errid = generatemsgid('invalidSegmentLength'); errmsg = 'The length of the segments cannot be greater than the length of the input signal.'; return; end if noverlap >= L, errid = generatemsgid('invalidNoverlap'); errmsg = 'The number of samples to overlap must be less than the length of the segments.'; return; end end %------------------------------------------------------------------------------ %WELCH_OPTIONS Parse the optional inputs to the PWELCH function. % WELCH_OPTIONS returns a structure, OPTIONS, with following fields: % % options.nfft - number of freq. points at which the psd is estimated % options.Fs - sampling freq. if any % options.range - 'onesided' or 'twosided' psd function [options,msg] = welch_options(isreal_x,N,varargin) % Generate defaults options.nfft = max(256,2^nextpow2(N)); options.Fs = []; % Work in rad/sample % Determine if frequency vector specified freqVecSpec = false; if (length(varargin) > 0 && length(varargin{1}) > 1) freqVecSpec = true; end if isreal_x && ~freqVecSpec, options.range = 'onesided'; else options.range = 'twosided'; end msg = ''; if any(strcmp(varargin, 'whole')) warning(generatemsgid('invalidRange'), '''whole'' is not a valid range, use ''twosided'' instead.'); elseif any(strcmp(varargin, 'half')) warning(generatemsgid('invalidRange'), '''half'' is not a valid range, use ''onesided'' instead.'); end [options,msg] = psdoptions(isreal_x,options,varargin{:}); end