1 | % 'signal_spectrum': calculate and display spectrum of the current field |
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2 | % operate on a 1D signal or the first dimension of a higher dimensional matrix (then average over other dimensions) |
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3 | % this function aplies the Welch method and call the function of the matlab signal processing toolbox |
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4 | % |
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5 | % OUTPUT: |
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6 | % DataOut: if DataIn.Action.RUN=0 (introducing parameters): Matlab structure containing the parameters |
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7 | % else transformed field, here not modified (the function just produces a plot on an independent fig) |
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8 | % |
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9 | % INPUT: |
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10 | % DataIn: Matlab structure containing the input field from the GUI uvmat, DataIn.Action.RUN=0 to set input parameters. |
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11 | % Param: structure containing processing parameters, created when DataIn.Action.RUN=0 at the first use of the transform fct |
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12 | |
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13 | %======================================================================= |
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14 | % Copyright 2008-2024, LEGI UMR 5519 / CNRS UGA G-INP, Grenoble, France |
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15 | % http://www.legi.grenoble-inp.fr |
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16 | % Joel.Sommeria - Joel.Sommeria (A) univ-grenoble-alpes.fr |
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17 | % |
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18 | % This file is part of the toolbox UVMAT. |
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19 | % |
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20 | % UVMAT is free software; you can redistribute it and/or modify |
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21 | % it under the terms of the GNU General Public License as published |
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22 | % by the Free Software Foundation; either version 2 of the license, |
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23 | % or (at your option) any later version. |
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24 | % |
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25 | % UVMAT is distributed in the hope that it will be useful, |
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26 | % but WITHOUT ANY WARRANTY; without even the implied warranty of |
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27 | % MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
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28 | % GNU General Public License (see LICENSE.txt) for more details. |
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29 | %======================================================================= |
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30 | |
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31 | function DataOut=signal_FFTMean(DataIn,Param) |
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32 | |
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33 | %% request input parameters |
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34 | if isfield(DataIn,'Action') && isfield(DataIn.Action,'RUN') && isequal(DataIn.Action.RUN,0) |
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35 | VarNbDim=cellfun('length',DataIn.VarDimName); |
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36 | [tild,rank]=sort(VarNbDim,2,'descend');% sort the list of input variables, putting the ones with higher dimensionality first |
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37 | ListVarName=DataIn.ListVarName(rank); |
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38 | VarDimName=DataIn.VarDimName(rank); |
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39 | InitialValue=1;%default choice |
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40 | if isfield(Param,'TransformInput') && isfield(Param.TransformInput,'VariableName') |
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41 | val=find(strcmp(Param.TransformInput.VariableName,ListVarName)); |
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42 | if ~isempty(val); |
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43 | InitialValue=val; |
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44 | end |
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45 | end |
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46 | [s,OK] = listdlg('PromptString','Select the variable to process:',... |
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47 | 'SelectionMode','single','InitialValue',InitialValue,... |
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48 | 'ListString',ListVarName); |
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49 | if OK==1 |
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50 | VarName=ListVarName{s}; |
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51 | DataOut.TransformInput.VariableName=VarName; |
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52 | dlg_title = [mfilename ' calulates spectra along first dim ' VarDimName{s}{1}];% title of the input dialog fig |
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53 | prompt = {'not used'};% titles of the edit boxes |
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54 | %default input: |
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55 | def={'512'};% window length |
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56 | np=size(DataIn.(VarName)); |
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57 | for idim=1:numel(np) % size restriction |
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58 | if idim==1 |
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59 | prompt=[prompt;{['index range for spectral dim ' VarDimName{s}{idim}]}];% titles of the edit boxes |
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60 | else |
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61 | prompt=[prompt;{['index range for ' VarDimName{s}{idim}]}];% titles of the edit boxes |
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62 | end |
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63 | def=[def;{num2str([1 np(idim)])}]; |
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64 | end |
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65 | if isfield(Param,'TransformInput') |
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66 | if isfield(Param.TransformInput,'WindowLength') |
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67 | def{1}=num2str(Param.TransformInput.WindowLength); |
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68 | end |
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69 | if isfield(Param.TransformInput,'IndexRange') |
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70 | for ilist=1:min(numel(np),size(Param.TransformInput.IndexRange,1)) |
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71 | def{ilist+1}=num2str(Param.TransformInput.IndexRange(ilist,:)); |
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72 | end |
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73 | end |
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74 | end |
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75 | num_lines= 1;%numel(prompt); |
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76 | % open the dialog fig |
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77 | answer = inputdlg(prompt,dlg_title,num_lines,def); |
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78 | DataOut.TransformInput.WindowLength=str2num(answer{1}); |
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79 | for ilist=1:numel(answer)-1 |
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80 | DataOut.TransformInput.IndexRange(ilist,1:2)=str2num(answer{ilist+1}); |
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81 | end |
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82 | end |
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83 | return |
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84 | end |
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85 | |
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86 | %% retrieve parameters |
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87 | DataOut=DataIn; |
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88 | WindowLength=Param.TransformInput.WindowLength; |
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89 | |
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90 | %% get the variable to process |
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91 | Var= DataIn.(Param.TransformInput.VariableName);%variable to analyse |
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92 | if isfield(Param.TransformInput,'IndexRange') |
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93 | IndexRange=Param.TransformInput.IndexRange; |
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94 | switch size(IndexRange,1) |
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95 | case 3 |
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96 | Var=Var(IndexRange(1,1):IndexRange(1,2),IndexRange(2,1):IndexRange(2,2),IndexRange(3,1):IndexRange(3,2)); |
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97 | case 2 |
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98 | Var=Var(IndexRange(1,1):IndexRange(1,2),IndexRange(2,1):IndexRange(2,2)); |
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99 | case 1 |
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100 | Var=Var(IndexRange(1,1):IndexRange(1,2)); |
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101 | end |
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102 | end |
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103 | np=size(Var);%dimensions of Var |
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104 | if ~isvector(Var) |
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105 | Var=reshape(Var,np(1),prod(np(2:end)));% reshape in a 2D matrix with time as first index |
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106 | end |
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107 | Var=Var-ones(np(1),1)*nanmean(Var,1); %substract mean value (excluding NaN) |
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108 | |
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109 | %% look for 'time' coordinate |
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110 | VarIndex=find(strcmp(Param.TransformInput.VariableName,DataIn.ListVarName)); |
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111 | TimeDimName=DataIn.VarDimName{VarIndex}{1}; |
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112 | TimeVarNameIndex=find(strcmp(TimeDimName,DataIn.ListVarName)); |
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113 | if isempty(TimeVarNameIndex) |
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114 | Time=1:np(1); |
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115 | TimeUnit='vector index'; |
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116 | else |
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117 | Time=DataIn.(DataIn.ListVarName{TimeVarNameIndex}); |
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118 | TimeUnit=['Unit of ' TimeDimName]; |
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119 | end |
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120 | % check time intervals |
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121 | diff_x=diff(Time); |
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122 | dx=min(diff_x); |
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123 | freq_max=1/(2*dx); |
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124 | check_interp=0; |
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125 | if diff_x>1.001*dx % non constant time interval |
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126 | check_interp=1; |
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127 | end |
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128 | |
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129 | %% claculate the spectrum |
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130 | specmean=0;% mean spectrum initialisation |
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131 | cospecmean=0; |
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132 | NbNan=0; |
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133 | NbPos=0; |
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134 | np_freq=floor(size(Var,1)/2); |
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135 | for pos=1:size(Var,2) |
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136 | sample=Var(:,pos);%extract sample to analyse |
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137 | ind_bad=find(isnan(sample)); |
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138 | ind_good=find(~isnan(sample)); |
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139 | % if numel(ind_good)>WindowLength |
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140 | NbPos=NbPos+1; |
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141 | if ~isempty(ind_bad) |
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142 | sample=sample(ind_good); % keep only non NaN data |
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143 | NbNan=NbNan+numel(ind_bad); |
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144 | end |
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145 | %interpolate if needed |
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146 | if ~isempty(ind_bad)||check_interp |
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147 | sample=interp1(Time(ind_good),sample,(Time(1):dx:Time(end))); %interpolated func |
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148 | sample(isnan(sample))=[]; |
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149 | end |
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150 | |
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151 | fourier=fft(sample);%take fft (complex) |
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152 | spec=abs(fourier).*abs(fourier);% take square of the modulus |
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153 | spec=spec(1:np_freq,:);%keep only the first half (the other is symmetric) |
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154 | specmean=spec+specmean; |
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155 | % end |
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156 | end |
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157 | specmean=specmean/NbPos; |
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158 | |
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159 | %plot spectrum in log log |
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160 | hfig=findobj('Tag','fig_spectrum'); |
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161 | if isempty(hfig)% create spectruim figure if it does not exist |
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162 | hfig=figure; |
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163 | set(hfig,'Tag','fig_spectrum'); |
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164 | else |
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165 | figure(hfig) |
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166 | end |
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167 | loglog(freq_max*(1:length(specmean))/length(specmean),specmean) |
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168 | set(gca,'YLim',[1.0000e-06*max(specmean) 1.1*max(specmean)]) |
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169 | title (['power spectrum of ' Param.TransformInput.VariableName ]) |
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170 | xlabel(['frequency (cycles per ' TimeUnit ')']) |
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171 | ylabel('spectral intensity') |
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172 | legend({'spectrum','cospectrum t t-1'}) |
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173 | get(gca,'Unit') |
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174 | sum(specmean) |
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175 | if NbPos~=size(Var,2) |
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176 | disp([ 'warning: ' num2str(size(Var,2)-NbPos) ' NaN sampled removed']) |
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177 | end |
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178 | if NbNan~=0 |
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179 | disp([ 'warning: ' num2str(NbNan) ' NaN values replaced by linear interpolation']) |
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180 | %text(0.9, 0.5,[ 'warning: ' num2str(NbNan) ' NaN values removed']) |
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181 | end |
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182 | grid on |
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183 | |
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184 | |
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