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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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% CONFINT Calculates confidence levels and variance for psd, lpsd, cohere, lcohere and curvefit parameters %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DESCRIPTION: CONFINT Input psd, mscohere (magnitude square coherence) % and return confidence levels and variance for them. % Spectra are assumed to be calculated with the WOSA method (Welch's % Overlapped Segment Averaging Method) % % CALL: out = confint(a,pl) % % % INPUTS: % a - input analysis objects containing power spectral % densities or magintude squared coherence. % pl - input parameter list % % OUTPUTS: % out - a collection object containing: % lcl - lower confidence level % ucl - upper confidence level % var - expected spectrum variance % % % If the last input argument is a parameter list (plist). % The following parameters are recognised. % % <a href="matlab:utils.helper.displayMethodInfo('ao', 'confint')">Parameters Description</a> % % % % % % VERSION: $Id: confint.m,v 1.20 2011/04/29 13:54:36 luigi Exp $ % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% function varargout = confint(varargin) %%% Check if this is a call for parameters if utils.helper.isinfocall(varargin{:}) varargout{1} = getInfo(varargin{3}); return end import utils.const.* utils.helper.msg(msg.PROC3, 'running %s/%s', mfilename('class'), mfilename); %%% Collect input variable names in_names = cell(size(varargin)); for ii = 1:nargin,in_names{ii} = inputname(ii);end %%% Collect all AOs [as, ao_invars] = utils.helper.collect_objects(varargin(:), 'ao', in_names); pl = utils.helper.collect_objects(varargin(:), 'plist', in_names); %%% avoid multiple AO at input if numel(as)>1 error('!!! Too many input AOs, CONFINT can process only one AO per time !!!') end %%% avoid input modification if nargout == 0 error('!!! CONFINT cannot be used as a modifier. Please give an output variable !!!'); end %%% Parse plists pl = parse(pl, getDefaultPlist()); %%% Find parameters mtd = lower(find(pl, 'method')); conf = find(pl, 'conf'); dof = find(pl, 'dof'); conf = conf/100; % go from percentage to fractional Ntot = find(pl,'DataLength'); %%% check that fsdata is input if ~isa(as.data, 'fsdata') error('!!! Non-fsdata input, CONFINT can process only fsdata !!!') end % looking to dof if isempty(dof) calcdof = true; else if isa(dof, 'ao') dof = dof.data.y; calcdof = false; else calcdof = false; end end %%% switching over methods switch mtd case 'psd' %%% confidence levels for spectra calculated with psd % calculating dof if calcdof dofs = getdof(as,plist('method',mtd,'DataLength',Ntot)); dof = dofs.y; end % if calcdof dof = round(dof); if length(dof)~=1 error('!!! CONFINT for ao/psd method, dof must be a single number') end % Calculating Confidence Levels factors alfa = 1 - conf; c = utils.math.Chi2inv([1-alfa/2 alfa/2],dof); c = dof./c; % calculating variance expvar = ((as.data.y).^2).*2./dof; % calculating confidence levels lwb = as.data.y.*c(1); upb = as.data.y.*c(2); case 'lpsd' %%% confidence levels for spectra calculated with lpsd % calculating dof if calcdof dofs = getdof(as,plist('method',mtd,'DataLength',Ntot)); dofs = dofs.y; % extract number of frequencies bins nf = length(as.x); cl = ones(nf,2); for jj=1:nf % Calculating Confidence Levels factors alfa = 1 - conf; c = utils.math.Chi2inv([1-alfa/2 alfa/2],dofs(jj)); c = dofs(jj)./c; % storing c cl(jj,1) = c(1); cl(jj,2) = c(2); end % for jj=1:nf else % if calcdof if length(dof)~=length(as.x) error('!!! CONFINT for ao/lpsd method, dof must be a vector of the same length of the frequencies vector') end dofs = round(dof); cl = ones(length(as.x),2); for jj = 1:length(as.x) % Calculating Confidence Levels factors alfa = 1 - conf; c = utils.math.Chi2inv([1-alfa/2 alfa/2],dofs(jj)); c = dofs(jj)./c; % storing c cl(jj,1) = c(1); cl(jj,2) = c(2); end end % if calcdof % willing to work with columns dy = as.data.y; [ii,kk] = size(dy); if ii<kk dy = dy.'; rsp = true; else rsp = false; end % calculating variance expvar = ((dy).^2).*2./dofs; % calculating confidence levels lwb = dy.*cl(:,1); upb = dy.*cl(:,2); % reshaping if necessary if rsp expvar = expvar.'; lwb = lwb.'; upb = upb.'; end case 'mscohere' %%% confidence levels for mscohere calculated with ao/cohere % calculating dof if calcdof dofs = getdof(as,plist('method',mtd,'DataLength',Ntot)); dof = dofs.y; end % if calcdof dof = round(dof); if length(dof)~=1 error('!!! CONFINT for ao/cohere method, dof must be a single number') end % Defining Y variable Y = atanh(sqrt(as.data.y)); % Calculating Confidence Levels factor alfa = 1 - conf; c = -sqrt(2).*erfcinv(2*(1-alfa/2))./sqrt(dof); Ylwb = Y - c; Yupb = Y + c; % calculating confidence levels lwb = tanh(Ylwb).^2; upb = tanh(Yupb).^2; % calculating variance expvar = ((1-(as.data.y).^2).^2).*((as.data.y).^2).*4./dof; case 'mslcohere' %%% confidence levels for spectra calculated with lpsd % calculating dof if calcdof dofs = getdof(as,plist('method',mtd,'DataLength',Ntot)); dofs = dofs.y; % extract number of frequencies bins nf = length(as.x); % willing to work with columns dy = as.data.y; [ii,kk] = size(dy); if ii<kk dy = dy.'; rsp = true; else rsp = false; end % Defining Y variable Y = atanh(sqrt(dy)); cl = ones(nf,2); for jj=1:nf % Calculating Confidence Levels factors alfa = 1 - conf; c = -sqrt(2).*erfcinv(2*(1-alfa/2))./sqrt(dofs(jj)); % storing c and dof cl(jj,1) = Y(jj) - c; cl(jj,2) = Y(jj) + c; end % for jj=1:nf else % if calcdof if length(dof)~=length(as.x) error('!!! CONFINT for ao/lcohere method, dof must be a vector of the same length of the frequencies vector') end dofs = round(dof); % willing to work with columns dy = as.data.y; [ii,kk] = size(dy); if ii<kk dy = dy.'; rsp = true; else rsp = false; end % Defining Y variable Y = atanh(sqrt(dy)); cl = ones(length(as.x),2); for jj = 1:length(as.x) % Calculating Confidence Levels factors alfa = 1 - conf; c = -sqrt(2).*erfcinv(2*(1-alfa/2))./sqrt(dofs(jj)); % storing c cl(jj,1) = Y(jj) - c; cl(jj,2) = Y(jj) + c; end end % if calcdof % calculating variance expvar = ((1-(dy).^2).^2).*((dy).^2).*4./dofs; % get not well defined coherence estimations idd = dofs<=2; % calculating confidence levels lwb = tanh(cl(:,1)); % remove negative elements idx = lwb < 0; lwb(idx) = 0; % set lower bound to zero in points where coharence is not well defined lwb(idd) = 0; upb = tanh(cl(:,2)); % set upper bound to one in points where coharence is not well % defined upb(idd) = 1; lwb = lwb.^2; upb = upb.^2; % reshaping if necessary if rsp expvar = expvar.'; lwb = lwb.'; upb = upb.'; end end %switch mtd % Output data % defining units inputunit = get(as.data,'yunits'); varunit = unit(inputunit.^2); varunit.simplify; levunit = inputunit; levunit.simplify; % variance plvar = plist('xvals', as.data.x, 'yvals', expvar, 'type', 'fsdata'); ovar = ao(plvar); ovar.setFs(as.data.fs); ovar.setT0(as.data.t0); ovar.data.setEnbw(as.data.enbw); ovar.data.setNavs(as.data.navs); ovar.setXunits(as.data.xunits); ovar.setYunits(varunit); % Set output AO name ovar.name = sprintf('var(%s)', ao_invars{:}); % lower confidence level pllwb = plist('xvals', as.data.x, 'yvals', lwb, 'type', 'fsdata'); olwb = ao(pllwb); olwb.setFs(as.data.fs); olwb.setT0(as.data.t0); olwb.data.setEnbw(as.data.enbw); olwb.data.setNavs(as.data.navs); olwb.setXunits(copy(as.data.xunits,1)); olwb.setYunits(levunit); % Set output AO name clev = [num2str(conf*100) '%']; olwb.name = sprintf('%s_low_conf_level(%s)', clev, ao_invars{:}); % upper confidence level plupb = plist('xvals', as.data.x, 'yvals', upb, 'type', 'fsdata'); oupb = ao(plupb); oupb.setFs(as.data.fs); oupb.setT0(as.data.t0); oupb.data.setEnbw(as.data.enbw); oupb.data.setNavs(as.data.navs); oupb.setXunits(copy(as.data.xunits,1)); oupb.setYunits(levunit); % Set output AO name oupb.name = sprintf('%s_up_conf_level(%s)', clev, ao_invars{:}); outobj = collection(olwb,oupb,ovar); outobj.setName(sprintf('%s conf levels for %s', clev, ao_invars{:})); outobj.addHistory(getInfo('None'), pl, [ao_invars(:)], [as.hist]); varargout{1} = outobj; end %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % Local Functions % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% %----- LTPDA FUNCTIONS ---------------------------------------------------- %-------------------------------------------------------------------------- % Get Info Object %-------------------------------------------------------------------------- function ii = getInfo(varargin) if nargin == 1 && strcmpi(varargin{1}, 'None') sets = {}; pl = []; else sets = {'Default'}; pl = getDefaultPlist; end % Build info object ii = minfo(mfilename, 'ao', 'ltpda', utils.const.categories.sigproc, '$Id: confint.m,v 1.20 2011/04/29 13:54:36 luigi Exp $', sets, pl); ii.setModifier(false); ii.setOutmin(2); ii.setOutmax(3); end %-------------------------------------------------------------------------- % Get Default Plist %-------------------------------------------------------------------------- function plout = getDefaultPlist() persistent pl; if exist('pl', 'var')==0 || isempty(pl) pl = buildplist(); end plout = pl; end function pl = buildplist() pl = ao.getInfo('getdof', 'Default').plists; % Conf p = param({'Conf', ['Required percentage confidence level.<br>' ... 'It is a number between 0 and 100.']}, ... {1, {95}, paramValue.OPTIONAL}); pl.pset(p); % DOF p = param({'dof', ['Degrees of freedom of the estimator. If it is<br>'... 'left empty they are calculated.']}, paramValue.EMPTY_DOUBLE); pl.pset(p); end % END