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view testing/utp_1.1/utps/ao/utp_ao_lcpsd.m @ 52:daf4eab1a51e database-connection-manager tip
Fix. Default password should be [] not an empty string
author | Daniele Nicolodi <nicolodi@science.unitn.it> |
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date | Wed, 07 Dec 2011 17:29:47 +0100 |
parents | 409a22968d5e |
children |
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% UTP_AO_LCPSD a set of UTPs for the ao/lcpsd method % % M Hewitson 06-08-08 % % $Id: utp_ao_lcpsd.m,v 1.29 2011/07/22 11:51:46 mauro Exp $ % % <MethodDescription> % % The lcpsd method of the ao class computes the cross-spectral density between two % time-series AOs on a log-frequency axis. % % </MethodDescription> function results = utp_ao_lcpsd(varargin) % Check the inputs if nargin == 0 % Some keywords class = 'ao'; mthd = 'lcpsd'; results = []; disp('******************************************************'); disp(['**** Running UTPs for ' class '/' mthd]); disp('******************************************************'); % Test AOs [at1,at2,at3,at4,at5,at6] = eval(['get_test_objects_' class]); % Exception list for the UTPs: [ple1,ple2,ple3,ple4,ple5,ple6] = get_test_ples(); % Get default window from the preferences prefs = getappdata(0, 'LTPDApreferences'); defaultWinType = char(prefs.getMiscPrefs.getDefaultWindow); % Run the tests results = [results utp_01]; % getInfo call results = [results utp_02]; % Vector input (only with two objects) results = [results utp_03]; % Matrix input (not possible) results = [results utp_04]; % List input (only with two objects) results = [results utp_05]; % Test with mixed input (not possible) results = [results utp_06]; % Test history is working results = [results utp_07]; % Test the modify call works results = [results utp_08]; % Test input data shape == output data shape results = [results utp_09]; % Test output of the data results = [results utp_11(mthd, [at1 at1], ple1)]; % Test plotinfo doesn't disappear results = [results utp_12]; % Test data lengths results = [results utp_17]; % Test units handling: LCPSD results = [results utp_18]; % Comparison with PSD disp('Done.'); disp('******************************************************'); elseif nargin == 1 % Check for UTP functions if strcmp(varargin{1}, 'isutp') results = 1; else results = 0; end else error('### Incorrect inputs') end %% UTP_01 % <TestDescription> % % Tests that the getInfo call works for this method. % % </TestDescription> function result = utp_01 % <SyntaxDescription> % % Test that the getInfo call works for no sets, all sets, and each set % individually. % % </SyntaxDescription> try % <SyntaxCode> % Call for no sets io(1) = eval([class '.getInfo(''' mthd ''', ''None'')']); % Call for all sets io(2) = eval([class '.getInfo(''' mthd ''')']); % Call for each set for kk=1:numel(io(2).sets) io(kk+2) = eval([class '.getInfo(''' mthd ''', ''' io(2).sets{kk} ''')']); end % </SyntaxCode> stest = true; catch err disp(err.message) stest = false; end % <AlgoDescription> % % 1) Check that getInfo call returned an minfo object in all cases. % 2) Check that all plists have the correct parameters. % % </AlgoDescription> atest = true; if stest % <AlgoCode> % check we have minfo objects if isa(io, 'minfo') % SET 'None' if ~isempty(io(1).sets), atest = false; end if ~isempty(io(1).plists), atest = false; end % Check all Sets if ~any(strcmpi(io(2).sets, 'Default')), atest = false; end if numel(io(2).plists) ~= numel(io(2).sets), atest = false; end % SET 'Default' if io(3).plists.nparams ~= 9, atest = false; end % Check key if ~io(3).plists.isparam('kdes'), atest = false; end if ~io(3).plists.isparam('jdes'), atest = false; end if ~io(3).plists.isparam('lmin'), atest = false; end if ~io(3).plists.isparam('win'), atest = false; end if ~io(3).plists.isparam('olap'), atest = false; end if ~io(3).plists.isparam('order'), atest = false; end if ~io(3).plists.isparam('psll'), atest = false; end if ~io(3).plists.isparam('times'), atest = false; end if ~io(3).plists.isparam('split'), atest = false; end % Check default value if ~isequal(io(3).plists.find('kdes'), 100), atest = false; end if ~isequal(io(3).plists.find('jdes'), 1000), atest = false; end if ~isequal(io(3).plists.find('lmin'), 0), atest = false; end if ~strcmpi(io(3).plists.find('win'), defaultWinType), atest = false; end if ~isequal(io(3).plists.find('olap'), -1), atest = false; end if ~isequal(io(3).plists.find('order'), 0), atest = false; end if ~isequal(io(3).plists.find('psll'), 200), atest = false; end if ~isEmptyDouble(io(3).plists.find('times')), atest = false; end if ~isEmptyDouble(io(3).plists.find('split')), atest = false; end % Check options if ~isequal(io(3).plists.getOptionsForParam('kdes'), {100}), atest = false; end if ~isequal(io(3).plists.getOptionsForParam('jdes'), {1000}), atest = false; end if ~isequal(io(3).plists.getOptionsForParam('lmin'), {0}), atest = false; end if ~isequal(io(3).plists.getOptionsForParam('win'), specwin.getTypes), atest = false; end if ~isequal(io(3).plists.getOptionsForParam('olap'), {-1}), atest = false; end if ~isequal(io(3).plists.getOptionsForParam('order'), {-1 0 1 2 3 4 5 6 7 8 9}), atest = false; end if ~isequal(io(3).plists.getOptionsForParam('psll'), {200}), atest = false; end if ~isequal(io(3).plists.getOptionsForParam('times'), {[]}), atest = false; end if ~isequal(io(3).plists.getOptionsForParam('split'), {[]}), atest = false; end end % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_01 %% UTP_02 % <TestDescription> % % Tests that the lcpsd method works with a vector of AOs as input. (only % with two objects in the vector) % % </TestDescription> function result = utp_02 % <SyntaxDescription> % % Test that the lcpsd method works for a vector of AOs as input. % % </SyntaxDescription> try % <SyntaxCode> avec = [at1 at5]; out = lcpsd(avec); % </SyntaxCode> stest = true; catch err disp(err.message) stest = false; end % <AlgoDescription> % % 1) Check that the number of elements in 'out' is equal to 1 % % </AlgoDescription> atest = true; if stest % <AlgoCode> % Check we have the correct number of outputs if numel(out) ~= 1, atest = false; end % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_02 %% UTP_03 % <TestDescription> % % Tests that the lcpsd method doesn't work with a matrix of AOs as input. % % </TestDescription> function result = utp_03 % <SyntaxDescription> % % Test that the lcpsd method doesn't work for a matrix of AOs as input. % % </SyntaxDescription> try % <SyntaxCode> amat = [at1 at5; at5 at6]; out = lcpsd(amat); % </SyntaxCode> stest = false; catch err stest = true; end % <AlgoDescription> % % 1) Nothing to check. % % </AlgoDescription> atest = true; if stest % <AlgoCode> % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_03 %% UTP_04 % <TestDescription> % % Tests that the lcpsd method works with a list of AOs as input. % % </TestDescription> function result = utp_04 % <SyntaxDescription> % % Test that the lcpsd method works for a list of AOs as input. % % </SyntaxDescription> try % <SyntaxCode> out = lcpsd(at1,at5); % </SyntaxCode> stest = true; catch err disp(err.message) stest = false; end % <AlgoDescription> % % 1) Check that the number of elements in 'out' is equal to 1 % % </AlgoDescription> atest = true; if stest % <AlgoCode> % Check we have the correct number of outputs if numel(out) ~= 1, atest = false; end % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_04 %% UTP_05 % <TestDescription> % % Tests that the lcpsd method doesn't work with a mix of different shaped % AOs as input. % % </TestDescription> function result = utp_05 % <SyntaxDescription> % % Test that the lcpsd method doesn't work with an input of matrices and % vectors and single AOs. % % </SyntaxDescription> try % <SyntaxCode> out = lcpsd(at1,[at5 at6],at5,[at5 at1; at6 at1],at6); stest = false; % </SyntaxCode> catch err stest = true; end % <AlgoDescription> % % 1) Nothing to check % % </AlgoDescription> atest = true; if stest % <AlgoCode> % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_05 %% UTP_06 % <TestDescription> % % Tests that the lcpsd method properly applies history. % % </TestDescription> function result = utp_06 % <SyntaxDescription> % % Test that the result of applying the lcpsd method can be processed back % to an m-file. % % </SyntaxDescription> try % <SyntaxCode> out = lcpsd(at5,at6); mout = rebuild(out); % </SyntaxCode> stest = true; catch err disp(err.message) stest = false; end % <AlgoDescription> % % 1) Check that the last entry in the history of 'out' corresponds to % 'cpsd'. % 2) Check that the re-built object is the same as 'out'. % % </AlgoDescription> atest = true; if stest % <AlgoCode> % Check the last step in the history of 'out' if ~strcmp(out.hist.methodInfo.mname, 'lcpsd'), atest = false; end % Check the re-built object if ~eq(mout, out, ple2), atest = false; end % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_06 %% UTP_07 % <TestDescription> % % Tests that the lcpsd method can not modify the input AO. % % </TestDescription> function result = utp_07 % <SyntaxDescription> % % Test that the lcpsd method can not modify the input AO. % The method must throw an error for the modifier call. % % </SyntaxDescription> try % <SyntaxCode> % copy at1 to work with ain = ao(at1); % modify ain ain.lcpsd(at5); % </SyntaxCode> stest = false; catch err stest = true; end % <AlgoDescription> % % 1) Nothing to check. % % </AlgoDescription> atest = true; if stest % <AlgoCode> % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_07 %% UTP_08 % <TestDescription> % % Test the shape of the output. % % </TestDescription> function result = utp_08 % <SyntaxDescription> % % Test that the lcpsd method keeps the data shape of the input object. The % input AO must be an AO with row data and an AO with column data. % % </SyntaxDescription> try % <SyntaxCode> out1 = lcpsd(at5, at6); out2 = lcpsd(at6, at5); % </SyntaxCode> stest = true; catch err disp(err.message) stest = false; end % <AlgoDescription> % % 1) Check that the shape of the output data doesn't change. % % </AlgoDescription> atest = true; if stest % <AlgoCode> % Check the shape of the output data if size(out1.data.y, 2) ~= 1, atest = false; end if size(out2.data.y, 1) ~= 1, atest = false; end % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_08 %% UTP_09 % <TestDescription> % % Check that the lcpsd method pass back the output objects to a list of % output variables or to a single variable. % % </TestDescription> function result = utp_09 % <SyntaxDescription> % % This test is not longer necessary because the lcpsd method pass back % always only one object. % % </SyntaxDescription> try % <SyntaxCode> % </SyntaxCode> stest = true; catch err disp(err.message) stest = false; end % <AlgoDescription> % % 1) Nothing to check. % % </AlgoDescription> atest = true; if stest % <AlgoCode> % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_09 %% UTP_12 % <TestDescription> % % Tests that differently sized data sets are treated properly % % </TestDescription> function result = utp_12 % <SyntaxDescription> % % Test that applying lcpsd works on two AOs. % % </SyntaxDescription> try % <SyntaxCode> % Construct two test AOs nsecs = [10000:1:20000]; fs = 1; pl = plist('fs', fs, 'tsfcn', 'randn(size(t))'); a1 = ao(pl.pset('nsecs', utils.math.randelement(nsecs, 1))); a2 = ao(pl.pset('nsecs', utils.math.randelement(nsecs, 1))); len_1 = a1.len; len_2 = a2.len; % Filter one time-series f2 = miir(plist('type', 'bandpass', 'fs', fs, 'order', 3, 'fc', [.050 .25])); a1f = filter(a1, plist('filter', f2)); % Compute lcpsd win = 'Hanning'; pl = plist('Win', win, 'order', -1); out = lcpsd(a2,a1f,pl); stest = true; % </SyntaxCode> catch err disp(err.message) stest = false; end % <AlgoDescription> % % 1) Check that lcpsd used the length of the shortest ao. % % </AlgoDescription> atest = true; if stest % <AlgoCode> % Compare the nfft with the length of the input data if out.x(1) ~= 1/min(len_1,len_2) atest = false; end % </AlgoCode> else atest = false; end % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_12 %% UTP_17 % <TestDescription> % % Tests handling of units: % 1) white noise produced from normal pdf, with a given mean value and % sigma (distribution's 1st and 2nd orders) % 2) white noise produced from normal pdf, with a given mean value and % sigma (distribution's 1st and 2nd orders) % 3) LCPSD of the white noise series % 4) compares the units of the input and output % % </TestDescription> function result = utp_17 % <SyntaxDescription> % % 1) Prepare the test tsdata: % white noise from normal distribution + offset % 2) Assign a random unit % 3) Prepare the test tsdata: % white noise from normal distribution + offset % 4) Assign a random unit % 5) LCPSD of the white noise % % </SyntaxDescription> % <SyntaxCode> try noise_type = 'Normal'; win_type = 'BH92'; [a_1, a_2, spec, spec1] = prepare_analyze_noise(win_type, noise_type, plist); stest = true; catch err disp(err.message) stest = false; end % </SyntaxCode> % <AlgoDescription> % % 1) Check that (calculated LCPSD yunits) equals % input_1 units*input_2 units/Hz % % </AlgoDescription> % <AlgoCode> atest = true; u = simplifyYunits(a_1.* a_2, plist('prefixes', false, 'exceptions', 'Hz')); if stest if ne(spec.Cxy.yunits, u.yunits * unit('Hz^-1')) || ne(spec.Cxy.xunits, unit('Hz')) atest = false; end if ne(spec.Cyx.yunits, u.yunits * unit('Hz^-1')) || ne(spec.Cyx.xunits, unit('Hz')) atest = false; end else atest = false; end % </AlgoCode> % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_17 %% UTP_18 % <TestDescription> % % Tests handling of units: % 1) white noise produced from normal pdf, with a given mean value and % sigma (distribution's 1st and 2nd orders) % 2) white noise produced from normal pdf, with a given mean value and % sigma (distribution's 1st and 2nd orders) % 3) LCPSD of the white noise series % % Comparison with LPSD: % 4) compares the off-diagonal terms to check they are complex-conjugated % 5) compares the diagonal terms with PSD of the individual noise % % </TestDescription> function result = utp_18 % <SyntaxDescription> % % 1) Prepare the test tsdata: % white noise from normal distribution + offset % 2) Assign a random unit % 3) Prepare the test tsdata: % white noise from normal distribution + offset % 4) Assign a random unit % 5) LCPSD of the white noise % 6) LPSD of the white noise % % </SyntaxDescription> % <SyntaxCode> try noise_type = 'Uniform'; win_type = 'BH92'; [a_1, a_2, spec, spec2] = prepare_analyze_noise(win_type, noise_type, plist); stest = true; catch err disp(err.message) stest = false; end % </SyntaxCode> % <AlgoDescription> % % 1) Check that LCPSD(x,y) equals conj(LCPSD(y,x)) % 2) Check that LCPSD(y,y) equals LPSD(y) % 3) Check that LCPSD(x,x) equals LPSD(x) % % </AlgoDescription> % <AlgoCode> atest = true; TOL = 1e-12; if stest if ne(spec.Cxy.y, conj(spec.Cyx.y)), atest = false; end if ne(spec.Cxy.x, spec.Cyx.x), atest = false; end if ne(spec.Cxx.data, spec.S_1.data) if any(abs(spec.Cxx.y - spec.S_1.y)./abs(spec.Cxx.y) > TOL) atest = false; end end if ne(spec.Cyy.data, spec.S_2.data) if any(abs(spec.Cyy.y - spec.S_2.y)./abs(spec.Cyy.y) > TOL) atest = false; end end else atest = false; end % </AlgoCode> % Return a result structure result = utp_prepare_result(atest, stest, dbstack, mfilename); end % END UTP_18 %% Helper function for window call construction function [a_1, a_2, spec1, spec2] = prepare_analyze_noise(win_type, noise_type, pli) % Array of parameters to pick from fs_list = [0.1;1;2;5;10]; nsecs_list = [20 100 1000:1000:10000]'; sigma_distr_list = [1e-6 2e-3 0.25 1:0.1:10]'; trend_0_list = [1e-6 2e-3 0.25 1:0.1:10]'; % Build time-series test data % Picks the values at random from the list fs = utils.math.randelement(fs_list, 1); nsecs = utils.math.randelement(nsecs_list, 1); sigma_distr_1 = utils.math.randelement(sigma_distr_list, 1); sigma_distr_2 = utils.math.randelement(sigma_distr_list, 1); trend_0_1 = utils.math.randelement(trend_0_list, 1); trend_0_2 = utils.math.randelement(trend_0_list, 1); % Pick units and prefix from those supported unit_list = unit.supportedUnits; % remove the first empty unit '' from the list, because then is it % possible that we add a prefix to an empty unit unit_list = unit_list(2:end); prefix_list = unit.supportedPrefixes; % White noise a_n = ao(plist('waveform', 'noise', ... 'type', noise_type, 'fs', fs, 'nsecs', nsecs, 'sigma', sigma_distr_1)); % Constant signal a_c = ao(trend_0_1); % Total signal a_1 = a_n + a_c; % White noise a_n = ao(plist('waveform', 'noise', ... 'type', noise_type, 'fs', fs, 'nsecs', nsecs, 'sigma', sigma_distr_2)); % Constant signal a_c = ao(trend_0_2); % Total signal a_2 = a_n + a_c; % Set units a_1.setYunits(unit([cell2mat(utils.math.randelement(prefix_list,1)) cell2mat(utils.math.randelement(unit_list,1))])); a_2.setYunits(unit([cell2mat(utils.math.randelement(prefix_list,1)) cell2mat(utils.math.randelement(unit_list,1))])); % Evaluate the lcpsd of the white noise time-series data olap = 0; detrend_order = 0; switch lower(win_type) case 'kaiser' psll = find(pli, 'psll'); if isempty(psll) psll = find(ao.getInfo('psd').plists, 'psll'); end pl_spec = plist('Win', win_type, 'psll', psll, 'olap', olap, 'order', detrend_order); otherwise pl_spec = plist('Win', win_type, 'olap', olap, 'order', detrend_order); end if find(pli, 'win_obj') % Calls the lcpsd applying the detrend and window internally % (passig window object) spec2.pl = pl_spec; spec2.Cxy = lcpsd(a_1, a_2, spec2.pl); spec2.Cyx = lcpsd(a_2, a_1, spec2.pl); spec2.Cxx = lcpsd(a_1, a_1, spec2.pl); spec2.Cyy = lcpsd(a_2, a_2, spec2.pl); spec2.S_1 = simplifyYunits(lpsd(a_1, spec2.pl), ... plist('prefixes', false, 'exceptions','Hz')); spec2.S_2 = simplifyYunits(lpsd(a_2, spec2.pl), ... plist('prefixes', false, 'exceptions','Hz')); else spec2 = struct; end % Calls the lcpsd applying the detrend and window internally % (passig window name) spec1.pl = pl_spec.pset('Win', win_type); spec1.Cxy = lcpsd(a_1, a_2, spec1.pl); spec1.Cyx = lcpsd(a_2, a_1, spec1.pl); spec1.Cxx = lcpsd(a_1, a_1, spec1.pl); spec1.Cyy = lcpsd(a_2, a_2, spec1.pl); spec1.S_1 = simplifyYunits(lpsd(a_1, spec1.pl), ... plist('prefixes', false, 'exceptions','Hz')); spec1.S_2 = simplifyYunits(lpsd(a_2, spec1.pl), ... plist('prefixes', false, 'exceptions','Hz')); end end