1 | % 'FFT2_detrend': calculate the 2D spectrum of the input scalar after removing the linear trend
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2 | %------------------------------------------------------------------------
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3 | %%%% Use the general syntax for transform fields with a single input %%%%
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4 | % OUTPUT:
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5 | % DataOut: output field structure
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6 | %
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7 | %INPUT:
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8 | % DataIn: first input field structure
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9 |
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10 | %=======================================================================
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11 | % Copyright 2008-2017, LEGI UMR 5519 / CNRS UGA G-INP, Grenoble, France
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12 | % http://www.legi.grenoble-inp.fr
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13 | % Joel.Sommeria - Joel.Sommeria (A) legi.cnrs.fr
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14 | %
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15 | % This file is part of the toolbox UVMAT.
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16 | %
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17 | % UVMAT is free software; you can redistribute it and/or modify
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18 | % it under the terms of the GNU General Public License as published
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19 | % by the Free Software Foundation; either version 2 of the license,
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20 | % or (at your option) any later version.
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21 | %
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22 | % UVMAT is distributed in the hope that it will be useful,
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23 | % but WITHOUT ANY WARRANTY; without even the implied warranty of
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24 | % MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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25 | % GNU General Public License (see LICENSE.txt) for more details.
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26 | %=======================================================================
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27 |
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28 | function DataOut=FFT2_detrend(DataIn)
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29 | %------------------------------------------------------------------------
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30 | DataOut=[];
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31 | if strcmp(DataIn,'*')
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32 | DataOut.InputFieldType='scalar';
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33 | return
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34 | end
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35 | %%%%%%%%%%%%%%%%%%%%%%%%%
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36 | [CellInfo,NbDim,errormsg]=find_field_cells(DataIn);
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37 | if ~isempty(errormsg)
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38 | DataOut.Txt=errormsg;
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39 | return
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40 | end
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41 | DataOut.ListVarName={};
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42 | DataOut.VarDimName={};
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43 | for ilist=1:numel(CellInfo)
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44 | if NbDim(ilist)==2 && numel(CellInfo{ilist}.CoordIndex)==2 % field with structured coordinates
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45 | %process coordinates
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46 | CoordName=DataIn.ListVarName(CellInfo{ilist}.CoordIndex);
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47 | x1 = DataIn.(CoordName{2}); y1 = DataIn.(CoordName{1});
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48 | [x y] = meshgrid(x1,y1);
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49 | coeff(1,1) = sum(sum(x.^2)); coeff(1,2) = sum(sum(x.*y)); coeff(1,3) = sum(sum(x));
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50 | coeff(2,1) = sum(sum(x.*y)); coeff(2,2) = sum(sum(y.^2)); coeff(2,3) = sum(sum(y));
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51 | coeff(3,1) = sum(sum(x)); coeff(3,2) = sum(sum(y)); coeff(3,3) = length(x1)*length(y1);
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52 | delta_x = x1(2) - x1(1); delta_y = y1(2) - y1(1);
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53 | Nx = length(x1); Ny = length(y1);
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54 | Nxa = 1:Nx; Nya = 1:Ny;
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55 | ssx = find(Nxa<Nx/2); ssy = find(Nya<Ny/2);
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56 | Nxa(Nx-ssx+1) = -Nxa(ssx)+1; Nya(Ny-ssy+1) = -Nya(ssy)+1;
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57 | [Nxa Ix] = sort(Nxa); [Nya Iy] = sort(Nya);
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58 | kx1 = (2*pi/delta_x/Nx)*(Nxa-1); ky1 = (2*pi/delta_y/Ny)*(Nya-1);
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59 | ss = find(ky1>=0); ky1 = ky1(ss);
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60 | [kx ky] = meshgrid(kx1,ky1);
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61 | DataOut.(CoordName{2}) = kx1; DataOut.(CoordName{1}) = ky1;
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62 | if isfield(DataIn,'CoordUnit')
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63 | DataOut.CoordUnit=[DataIn.CoordUnit '^{-1}'];
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64 | DataOut.ListGlobalAttribute={'CoordUnit'};
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65 | end
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66 | %process scalar
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67 | ivar=CellInfo{ilist}.VarIndex_scalar(1);
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68 | VarName=DataIn.ListVarName{ivar};
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69 | z=DataIn.(VarName);
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70 | rhs(1) = sum(sum(x.*z)); rhs(2) = sum(sum(y.*z)); rhs(3) = sum(sum(z));
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71 | lin_coeff = inv(coeff)*rhs';
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72 | lin_trend = lin_coeff(1)*x + lin_coeff(2)*y + lin_coeff(3);
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73 | z2 = z - lin_trend;
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74 | spec2 = abs(fft2(z2)).^2;
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75 | spec2 = spec2(Iy,Ix);
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76 | spec2 = spec2(ss,:);
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77 | %DataOut.(VarName) = log(spec2);
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78 | DataOut.(VarName) = spec2;
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79 | spec_sum=sum(sum(spec2));
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80 | kx_mean=sum(sum(spec2.*kx))/spec_sum;
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81 | ky_mean=sum(sum(spec2.*ky))/spec_sum;
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82 | theta=atand(ky_mean/kx_mean);
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83 | lambda=2*pi/(sqrt(kx_mean*kx_mean+ky_mean*ky_mean));
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84 |
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85 | DataOut.ListVarName=[CoordName {VarName}];%list of variables
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86 | DataOut.VarDimName=[CoordName {CoordName}];%list of dimensions for variables
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87 | break
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88 | end
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89 | end
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90 |
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91 |
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92 |
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