[574] | 1 | %'phys_polar': transforms image (Unit='pixel') to polar (phys) coordinates using geometric calibration parameters
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| 2 | %------------------------------------------------------------------------
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| 3 | %%%% Use the general syntax for transform fields %%%%
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| 4 | % OUTPUT:
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[1078] | 5 | % Data: output field structure
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[574] | 6 | % .X=radius, .Y=azimuth angle, .U, .V are radial and azimuthal velocity components
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[810] | 7 | %
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[574] | 8 | %INPUT:
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| 9 | % DataIn: first input field structure
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| 10 | % XmlData: first input parameter structure,
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| 11 | % .GeometryCalib: substructure of the calibration parameters
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| 12 | % DataIn_1: optional second input field structure
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| 13 | % XmlData_1: optional second input parameter structure
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| 14 | % .GeometryCalib: substructure of the calibration parameters
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[172] | 15 | % transform image coordinates (px) to polar physical coordinates
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[1078] | 16 | %[Data,Data_1]=phys_polar(varargin)
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[40] | 17 | %
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| 18 | % OUTPUT:
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[1078] | 19 | % Data: structure of modified data field: .X=radius, .Y=azimuth angle, .U, .V are radial and azimuthal velocity components
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| 20 | % Data_1: second data field (if two fields are in input)
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[40] | 21 | %
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| 22 | %INPUT:
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| 23 | % Data: structure of input data (like UvData)
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[658] | 24 | % XmlData= structure containing the field .GeometryCalib with calibration parameters
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[40] | 25 | % Data_1: second input field (not mandatory)
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[658] | 26 | % XmlData_1= calibration parameters for the second field
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[810] | 27 |
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| 28 | %=======================================================================
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[1107] | 29 | % Copyright 2008-2022, LEGI UMR 5519 / CNRS UGA G-INP, Grenoble, France
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[810] | 30 | % http://www.legi.grenoble-inp.fr
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| 31 | % Joel.Sommeria - Joel.Sommeria (A) legi.cnrs.fr
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| 32 | %
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| 33 | % This file is part of the toolbox UVMAT.
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| 34 | %
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| 35 | % UVMAT is free software; you can redistribute it and/or modify
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| 36 | % it under the terms of the GNU General Public License as published
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| 37 | % by the Free Software Foundation; either version 2 of the license,
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| 38 | % or (at your option) any later version.
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| 39 | %
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| 40 | % UVMAT is distributed in the hope that it will be useful,
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| 41 | % but WITHOUT ANY WARRANTY; without even the implied warranty of
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| 42 | % MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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| 43 | % GNU General Public License (see LICENSE.txt) for more details.
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| 44 | %=======================================================================
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| 45 |
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[1078] | 46 | function Data=phys_polar(DataIn,XmlData,DataIn_1,XmlData_1)
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[574] | 47 | %------------------------------------------------------------------------
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[1078] | 48 |
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[933] | 49 | %% request input parameters
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| 50 | if isfield(DataIn,'Action') && isfield(DataIn.Action,'RUN') && isequal(DataIn.Action.RUN,0)
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[1084] | 51 | prompt = {'origin [x y] of polar coordinates';'reference radius';'reference angle(degrees)';'angle direction and switch x y(+/-)'};
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[933] | 52 | dlg_title = 'set the parameters for the polar coordinates';
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| 53 | num_lines= 2;
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[1094] | 54 | def = { '[0 0]';'';'0';'+'};
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[933] | 55 | if isfield(XmlData,'TransformInput')
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| 56 | if isfield(XmlData.TransformInput,'PolarCentre')
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| 57 | def{1}=num2str(XmlData.TransformInput.PolarCentre);
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| 58 | end
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| 59 | if isfield(XmlData.TransformInput,'PolarReferenceRadius')
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| 60 | def{2}=num2str(XmlData.TransformInput.PolarReferenceRadius);
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| 61 | end
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| 62 | if isfield(XmlData.TransformInput,'PolarReferenceAngle')
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| 63 | def{3}=num2str(XmlData.TransformInput.PolarReferenceAngle);
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| 64 | end
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[1084] | 65 | if isfield(XmlData.TransformInput,'PolarAngleDirection')
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| 66 | def{4}=XmlData.TransformInput.PolarAngleDirection;
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| 67 | end
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[933] | 68 | end
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| 69 | answer = inputdlg(prompt,dlg_title,num_lines,def);
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[1078] | 70 | Data.TransformInput.PolarCentre=str2num(answer{1});
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| 71 | Data.TransformInput.PolarReferenceRadius=str2num(answer{2});
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| 72 | Data.TransformInput.PolarReferenceAngle=str2num(answer{3});
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[1084] | 73 | Data.TransformInput.PolarAngleDirection=answer{4};
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[933] | 74 | return
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| 75 | end
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| 76 |
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[1078] | 77 | %% default outputs
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| 78 | Data=DataIn; %default output
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| 79 | if isfield(Data,'CoordUnit')
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[1112] | 80 | Data=rmfield(Data,'CoordUnit');
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[1078] | 81 | end
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| 82 | Data.ListVarName = {};
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| 83 | Data.VarDimName={};
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| 84 | Data.VarAttribute={};
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| 85 | DataCell{1}=DataIn;
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[40] | 86 | Calib{1}=[];
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[1112] | 87 | Slice{1}=[];
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[1078] | 88 | DataCell{2}=[];%default
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| 89 | checkpixel(1)=0;
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[1112] | 90 | if isfield(DataCell{1},'CoordUnit')&& strcmp(DataCell{1}.CoordUnit,'pixel')
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[1078] | 91 | checkpixel(1)=1;
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| 92 | end
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[40] | 93 | if nargin==2||nargin==4
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[1078] | 94 | if isfield(XmlData,'GeometryCalib') && ~isempty(XmlData.GeometryCalib)&& checkpixel(1)
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[658] | 95 | Calib{1}=XmlData.GeometryCalib;
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[40] | 96 | end
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[1112] | 97 | Slice{1}=Calib{1};
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| 98 | if isfield(XmlData,'Slice')
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| 99 | Slice{1}=XmlData.Slice;
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| 100 | end
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[40] | 101 | Calib{2}=Calib{1};
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[1112] | 102 | Slice{2}=Slice{1};
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[40] | 103 | else
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[1078] | 104 | Data.Txt='wrong input: need two or four structures';
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[40] | 105 | end
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[1078] | 106 | nbinput=1;
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[93] | 107 | if nargin==4% case of two input fields
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[1078] | 108 | checkpixel(2)=0;
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[1112] | 109 | if isfield(DataCell{2},'CoordUnit')&& strcmp(DataCell{2}.CoordUnit,'pixel')
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| 110 | checkpixel(2)=1;
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| 111 | end
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[1078] | 112 | DataCell{2}=DataIn_1;%default
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| 113 | if isfield(XmlData_1,'GeometryCalib')&& ~isempty(XmlData_1.GeometryCalib) && checkpixel(2)
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[658] | 114 | Calib{2}=XmlData_1.GeometryCalib;
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[40] | 115 | end
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[1112] | 116 | if isfield(XmlData_1,'Slice')
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| 117 | Slice{2}=XmlData_1.Slice;
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| 118 | end
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[1078] | 119 | nbinput=2;
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[40] | 120 | end
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| 121 |
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[1078] | 122 | %% parameters for polar coordinates (taken from the calibration data of the first field)
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[40] | 123 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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| 124 | origin_xy=[0 0];%center for the polar coordinates in the original x,y coordinates
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[933] | 125 | radius_offset=0;%reference radius used to offset the radial coordinate r
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| 126 | angle_offset=0; %reference angle used as new origin of the polar angle (= axis Ox by default)
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[1078] | 127 | angle_scale=180/pi;
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[1104] | 128 | check_reverse=false;
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[1078] | 129 | check_degree=1;%angle expressed in degrees by default
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[933] | 130 | if isfield(XmlData,'TransformInput')
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| 131 | if isfield(XmlData.TransformInput,'PolarCentre') && isnumeric(XmlData.TransformInput.PolarCentre)
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[1078] | 132 | if isequal(length(XmlData.TransformInput.PolarCentre),2)
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[933] | 133 | origin_xy= XmlData.TransformInput.PolarCentre;
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| 134 | end
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[40] | 135 | end
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[1094] | 136 | if isfield(XmlData.TransformInput,'PolarReferenceRadius') && ~isempty(XmlData.TransformInput.PolarReferenceRadius)
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[933] | 137 | radius_offset=XmlData.TransformInput.PolarReferenceRadius;
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| 138 | end
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| 139 | if radius_offset > 0
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| 140 | angle_scale=radius_offset; %the azimuth is rescale in terms of the length along the reference radius
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[1094] | 141 | check_degree=0; %the output has the same unit as the input
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[933] | 142 | else
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| 143 | angle_scale=180/pi; %polar angle in degrees
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[1078] | 144 | check_degree=1;%angle expressed in degrees
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[933] | 145 | end
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| 146 | if isfield(XmlData.TransformInput,'PolarReferenceAngle') && isnumeric(XmlData.TransformInput.PolarReferenceAngle)
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| 147 | angle_offset=(pi/180)*XmlData.TransformInput.PolarReferenceAngle; %offset angle (in unit of the final angle, degrees or arc length along the reference radius))
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| 148 | end
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[1084] | 149 | check_reverse=isfield(XmlData.TransformInput,'PolarAngleDirection')&& strcmp(XmlData.TransformInput.PolarAngleDirection,'-');
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[40] | 150 | end
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| 151 |
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| 152 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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[1078] | 153 | %% get fields
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[1084] | 154 |
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[1078] | 155 | nbvar=0;%counter for the number of output variables
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[1094] | 156 | nbcoord=0;%counter for the number of variablecheck_degrees for radial coordiantes (case of multiple field inputs)
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[1078] | 157 | nbgrid=0;%counter for the number of gridded fields (all linearly interpolated on the same output polar grid)
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| 158 | nbscattered=0;%counter of scattered fields
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| 159 | radius_name='radius';
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| 160 | theta_name='theta';
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| 161 | U_r_name='U_r';
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| 162 | U_theta_name='U_theta';
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| 163 | for ifield=1:nbinput %1 or 2 input fields
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| 164 | [CellInfo,NbDim,errormsg]=find_field_cells(DataCell{ifield});
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| 165 | if ~isempty(errormsg)
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| 166 | Data.Txt=['bad input to phys_polar: ' errormsg];
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| 167 | return
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[40] | 168 | end
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| 169 | %transform of X,Y coordinates for vector fields
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[1078] | 170 | if isfield(DataCell{ifield},'ZIndex')&& ~isempty(DataCell{ifield}.ZIndex)
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| 171 | ZIndex=DataCell{ifield}.ZIndex;
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[40] | 172 | else
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| 173 | ZIndex=0;
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| 174 | end
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[1084] | 175 | check_scalar=zeros(1,numel(CellInfo));
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| 176 | check_vector=zeros(1,numel(CellInfo));
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[1078] | 177 | for icell=1:numel(CellInfo)
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| 178 | if NbDim(icell)==2
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| 179 | % case of input field with scattered coordinates
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| 180 | if strcmp(CellInfo{icell}.CoordType,'scattered')
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| 181 | nbscattered=nbscattered+1;
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| 182 | nbcoord=nbcoord+1;
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| 183 | radius_name = rename_indexing(radius_name,Data.ListVarName);
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| 184 | theta_name = rename_indexing(theta_name,Data.ListVarName);
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| 185 | Data.ListVarName = [Data.ListVarName {radius_name} {theta_name}];
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| 186 | dim_name = rename_indexing('nb_point',Data.VarDimName);
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| 187 | Data.VarDimName=[Data.VarDimName {dim_name} {dim_name}];
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| 188 | nbvar=nbvar+2;
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| 189 | Data.VarAttribute{nbvar-1}.Role='coord_x';
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| 190 | check_unit=1;
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[1094] | 191 | %unit of output field
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| 192 | if isfield(XmlData,'GeometryCalib')&& isfield(XmlData.GeometryCalib,'CoordUnit')
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| 193 | radius_unit=XmlData.GeometryCalib.CoordUnit;% states that the output is in unit defined by GeometryCalib, then erased all projection objects with different units
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| 194 | elseif isfield(DataCell{ifield},'CoordUnit')
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| 195 | radius_unit=DataCell{ifield}.CoordUnit;
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[1078] | 196 | else
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[1094] | 197 | radius_unit='';
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[1078] | 198 | end
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[1094] | 199 | Data.VarAttribute{nbvar-1}.units=radius_unit;
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[1078] | 200 | if check_degree
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[1094] | 201 | Data.VarAttribute{nbvar}.units='degree';
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| 202 | else %case of a reference radius
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| 203 | Data.VarAttribute{nbvar}.units=radius_unit;
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| 204 | Data.CoordUnit=radius_unit;
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[1078] | 205 | end
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[1094] | 206 | % if isfield(DataCell{ifield},'CoordUnit')
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| 207 | % Data=rmfield(Data,'CoordUnit');
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| 208 | % Data.VarAttribute{nbvar-1}.unit=DataCell{ifield}.CoordUnit;
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| 209 | % elseif isfield(XmlData,'GeometryCalib')&& isfield(XmlData.GeometryCalib,'CoordUnit')
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| 210 | % Data.VarAttribute{nbvar-1}.unit=XmlData.GeometryCalib.CoordUnit;% states that the output is in unit defined by GeometryCalib, then erased all projection objects with different units
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| 211 | % else
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| 212 | % check_unit=0;
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| 213 | % end
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| 214 | Data.VarAttribute{nbvar}.Role='coord_y';
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| 215 | % if check_degree
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| 216 | % Data.VarAttribute{nbvar}.units='degree';
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| 217 | % elseif check_unit
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| 218 | % Data.VarAttribute{nbvar}.units=Data.VarAttribute{nbvar-1}.units;
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| 219 | % end
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[1078] | 220 |
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| 221 | %transform u,v into polar coordinates
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| 222 | X=DataCell{ifield}.(CellInfo{icell}.XName);
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| 223 | Y=DataCell{ifield}.(CellInfo{icell}.YName);
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| 224 | if isfield(CellInfo{icell},'VarIndex_vector_x')&& isfield(CellInfo{icell},'VarIndex_vector_y')
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| 225 | UName=DataCell{ifield}.ListVarName{CellInfo{icell}.VarIndex_vector_x};
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| 226 | VName=DataCell{ifield}.ListVarName{CellInfo{icell}.VarIndex_vector_y};
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| 227 | if ~isempty(Calib{ifield})
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| 228 | [X,Y,Z,DataCell{ifield}.(UName),DataCell{ifield}.(VName)]=...
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[1112] | 229 | phys_XYUV(DataCell{ifield},Calib{ifield},Slice{ifield},ZIndex);
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[1078] | 230 | end
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| 231 | end
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| 232 | [Theta,Radius] = cart2pol(X-origin_xy(1),Y-origin_xy(2));
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| 233 | Data.(radius_name)=Radius-radius_offset;
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| 234 | Data.(theta_name)=Theta*angle_scale-angle_offset;
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| 235 | if Z~=0
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| 236 | Data.Z=Z;
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| 237 | nbvar=nbvar+1;
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| 238 | Data.ListVarName = [Data.ListVarName {'Z'}];
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| 239 | Data.VarDimName=[Data.VarDimName {dim_name}];
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| 240 | Data.VarAttribute{nbvar}.Role='coord_z';
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| 241 | end
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| 242 | if isfield(CellInfo{icell},'VarIndex_scalar')
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| 243 | ScalarName=DataCell{ifield}.ListVarName{CellInfo{icell}.VarIndex_scalar};
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| 244 | ScalarName=rename_indexing(ScalarName,Data.ListVarName);
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| 245 | Data.(ScalarName)=DataCell{ifield}.(ScalarName);
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| 246 | nbvar=nbvar+1;
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| 247 | Data.ListVarName = [Data.ListVarName {ScalarName}];
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| 248 | Data.VarDimName=[Data.VarDimName {dim_name}];
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| 249 | Data.VarAttribute{nbvar}.Role='scalar';
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| 250 | end
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| 251 | if isfield(CellInfo{icell},'VarIndex_vector_x')&& isfield(CellInfo{icell},'VarIndex_vector_y')
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| 252 | U_r_name= rename_indexing(U_r_name,Data.ListVarName);
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| 253 | U_theta_name= rename_indexing(U_theta_name,Data.ListVarName);
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| 254 | Data.(U_r_name)=DataCell{ifield}.(UName).*cos(Theta)+DataCell{ifield}.(VName).*sin(Theta);%radial velocity
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| 255 | Data.(U_theta_name)=(-DataCell{ifield}.(UName).*sin(Theta)+DataCell{ifield}.(VName).*cos(Theta));%./(Data.X)%+radius_ref);% azimuthal velocity component
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| 256 | Data.ListVarName = [Data.ListVarName {U_r_name} {U_theta_name}];
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| 257 | Data.VarDimName=[Data.VarDimName {dim_name} {dim_name}];
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| 258 | Data.VarAttribute{nbvar+1}.Role='vector_x';
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| 259 | Data.VarAttribute{nbvar+2}.Role='vector_y';
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| 260 | nbvar=nbvar+2;
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| 261 | end
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| 262 | if isfield(CellInfo{icell},'VarIndex_errorflag')
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| 263 | error_flag_name=DataCell{ifield}.ListVarName{CellInfo{icell}.VarIndex_errorflag};
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| 264 | error_flag_newname= rename_indexing(error_flag_name,Data.ListVarName);
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| 265 | Data.(error_flag_newname)=DataCell{ifield}.(error_flag_name);
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| 266 | Data.ListVarName = [Data.ListVarName {error_flag_newname}];
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| 267 | Data.VarDimName=[Data.VarDimName {dim_name}];
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| 268 | nbvar=nbvar+1;
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| 269 | Data.VarAttribute{nbvar}.Role='errorflag';
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| 270 | end
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| 271 |
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| 272 | %caseof input fields on gridded coordinates (matrix)
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| 273 | elseif strcmp(CellInfo{icell}.CoordType,'grid')
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| 274 | if nbgrid==0% no gridded data yet, introduce the coordinate variables common to all gridded data
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| 275 | nbcoord=nbcoord+1;%add new radial coordinates for the first gridded field
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[1094] | 276 | radius_name = rename_indexing(radius_name,Data.ListVarName);% add an index to the name, or increment an existing index,
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| 277 | theta_name = rename_indexing(theta_name,Data.ListVarName);% if the proposed Name already exists in the list
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| 278 | Data.ListVarName = [Data.ListVarName {radius_name} {theta_name}];%add polar coordinates to the list of variables
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[1078] | 279 | Data.VarDimName=[Data.VarDimName {radius_name} {theta_name}];
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| 280 | nbvar=nbvar+2;
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[1084] | 281 | if check_reverse
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[1094] | 282 | Data.VarAttribute{nbvar-1}.Role='coord_y';
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| 283 | Data.VarAttribute{nbvar}.Role='coord_x';
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[1084] | 284 | else
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[1094] | 285 | Data.VarAttribute{nbvar-1}.Role='coord_x';
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| 286 | Data.VarAttribute{nbvar}.Role='coord_y';
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[1084] | 287 | end
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[1078] | 288 | check_unit=1;
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[1094] | 289 |
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| 290 | if isfield(XmlData,'GeometryCalib')&& isfield(XmlData.GeometryCalib,'CoordUnit')
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| 291 | Data.VarAttribute{nbvar-1}.units=XmlData.GeometryCalib.CoordUnit;% states that the output is in unit defined by GeometryCalib, then erased all projection objects with different units
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| 292 | elseif isfield(DataCell{ifield},'CoordUnit')
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| 293 | Data.VarAttribute{nbvar-1}.units=DataCell{ifield}.CoordUnit;%radius in coord units
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[1078] | 294 | else
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| 295 | check_unit=0;
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| 296 | end
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| 297 | if check_degree
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[1094] | 298 | Data.VarAttribute{nbvar}.units='degree';%angle in degree
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[1078] | 299 | elseif check_unit
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[1094] | 300 | Data.VarAttribute{nbvar}.units=Data.VarAttribute{nbvar-1}.units;% angle in coord unit (normalised by reference radiuss)
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[1078] | 301 | end
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| 302 | end
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| 303 | if isfield(CellInfo{icell},'VarIndex_scalar')
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| 304 | nbgrid=nbgrid+1;
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| 305 | nbvar=nbvar+1;
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| 306 | Data.VarAttribute{nbvar}.Role='scalar';
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| 307 | FieldName{nbgrid}=DataCell{ifield}.ListVarName{CellInfo{icell}.VarIndex_scalar};
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| 308 | A{nbgrid}=DataCell{ifield}.(FieldName{nbgrid});
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| 309 | nbpoint(nbgrid)=numel(A{nbgrid});
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| 310 | check_scalar(nbgrid)=1;
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| 311 | coord_x{nbgrid}=DataCell{ifield}.(DataCell{ifield}.ListVarName{CellInfo{icell}.XIndex});
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| 312 | coord_y{nbgrid}=DataCell{ifield}.(DataCell{ifield}.ListVarName{CellInfo{icell}.YIndex});
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| 313 | ZInd(nbgrid)=ZIndex;
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| 314 | Calib_new{nbgrid}=Calib{ifield};
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[1112] | 315 | Slice_new{nbgrid}=Slice{ifield};
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[1078] | 316 | end
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| 317 | if isfield(CellInfo{icell},'VarIndex_vector_x')&& isfield(CellInfo{icell},'VarIndex_vector_y')
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| 318 | FieldName{nbgrid+1}=DataCell{ifield}.ListVarName{CellInfo{icell}.VarIndex_vector_x};
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| 319 | FieldName{nbgrid+2}=DataCell{ifield}.ListVarName{CellInfo{icell}.VarIndex_vector_y};
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| 320 | A{nbgrid+1}=DataCell{ifield}.(FieldName{nbgrid+1});
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| 321 | A{nbgrid+2}=DataCell{ifield}.(FieldName{nbgrid+2});
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[1094] | 322 | % Data.ListVarName=[Data.ListVarName {'U_r','U_theta'}];
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[1078] | 323 | %Data.VarDimName=[Data.VarDimName {{theta_name,radius_name}} {{theta_name,radius_name}}];
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| 324 | Data.VarAttribute{nbvar+1}.Role='vector_x';
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| 325 | Data.VarAttribute{nbvar+2}.Role='vector_y';
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| 326 | nbpoint([nbgrid+1 nbgrid+2])=numel(A{nbgrid+1});
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| 327 | check_vector(nbgrid+1)=1;
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| 328 | check_vector(nbgrid+2)=1;
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| 329 | coord_x{nbgrid+1}=DataCell{ifield}.(DataCell{ifield}.ListVarName{CellInfo{icell}.XIndex});
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| 330 | coord_y{nbgrid+1}=DataCell{ifield}.(DataCell{ifield}.ListVarName{CellInfo{icell}.YIndex});
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| 331 | coord_x{nbgrid+2}=DataCell{ifield}.(DataCell{ifield}.ListVarName{CellInfo{icell}.XIndex});
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| 332 | coord_y{nbgrid+2}=DataCell{ifield}.(DataCell{ifield}.ListVarName{CellInfo{icell}.YIndex});
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| 333 | ZInd(nbgrid+1)=ZIndex;
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| 334 | ZInd(nbgrid+2)=ZIndex;
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| 335 | Calib_new{nbgrid+1}=Calib{ifield};
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| 336 | Calib_new{nbgrid+2}=Calib{ifield};
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[1112] | 337 | Slice_new{nbgrid+1}=Calib{ifield};
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| 338 | Slice_new{nbgrid+2}=Calib{ifield};
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[1078] | 339 | nbgrid=nbgrid+2;
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| 340 | nbvar=nbvar+2;
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| 341 | end
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| 342 | end
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| 343 | end
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| 344 | end
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[40] | 345 | end
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[567] | 346 |
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[1078] | 347 | %% tranform cartesian to polar coordinates for gridded data
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| 348 | if nbgrid~=0
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[1112] | 349 | [A,Data.radius,Data.theta]=phys_Ima_polar(A,coord_x,coord_y,Calib_new,Slice_new,ZInd,origin_xy,radius_offset,angle_offset,angle_scale);
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[1078] | 350 | for icell=1:numel(A)
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[1084] | 351 | if icell<=numel(A)-1 && check_vector(icell)==1 && check_vector(icell+1)==1 %transform u,v into polar coordinates
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[1078] | 352 | theta=Data.theta/angle_scale-angle_offset;
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| 353 | [~,Theta]=meshgrid(Data.radius,theta);%grid in physical coordinates
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| 354 | U_r_name= rename_indexing(U_r_name,Data.ListVarName);
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[1084] | 355 | U_theta_name= rename_indexing(U_theta_name,Data.ListVarName);
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| 356 | Data.(U_r_name)=A{icell}.*cos(Theta)+A{icell+1}.*sin(Theta);%radial velocity
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| 357 | Data.(U_theta_name)=(-A{icell}.*sin(Theta)+A{icell+1}.*cos(Theta));% azimuthal velocity component
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| 358 | if check_reverse
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| 359 | Data.(U_theta_name)=(Data.(U_theta_name))';
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| 360 | Data.(U_r_name)=Data.(U_r_name)';
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| 361 | Data.ListVarName=[Data.ListVarName {U_theta_name,U_r_name}];
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| 362 | Data.VarDimName=[Data.VarDimName {{radius_name,theta_name}} {{radius_name,theta_name}}];
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| 363 | else
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| 364 | Data.ListVarName=[Data.ListVarName {U_r_name,U_theta_name}];
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| 365 | Data.VarDimName=[Data.VarDimName {{theta_name,radius_name}} {{theta_name,radius_name}}];
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| 366 | end
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[1078] | 367 | elseif ~check_vector(icell)% for scalar fields
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| 368 | FieldName{icell}= rename_indexing(FieldName{icell},Data.ListVarName);
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[1084] | 369 | Data.ListVarName=[Data.ListVarName FieldName(icell)];
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| 370 | if check_reverse
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| 371 | Data.(FieldName{icell})=A{icell}';
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| 372 | Data.VarDimName=[Data.VarDimName {{radius_name,theta_name}}];
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| 373 | else
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| 374 | Data.VarDimName=[Data.VarDimName {{theta_name,radius_name}}];
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| 375 | Data.(FieldName{icell})=A{icell};
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| 376 | end
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[1078] | 377 | end
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[40] | 378 | end
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| 379 | end
|
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[1084] | 380 | if check_reverse
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| 381 | Data.(theta_name)=-Data.(theta_name);
|
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| 382 | end
|
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[40] | 383 |
|
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[161] | 384 |
|
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[40] | 385 | %------------------------------------------------
|
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[1078] | 386 | %--- transform a single field into phys coordiantes
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[1112] | 387 | function [X,Y,Z,U,V]=phys_XYUV(Data,Calib,Slice,ZIndex)
|
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[1078] | 388 | %------------------------------------------------
|
---|
| 389 | %% set default output
|
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| 390 | %DataOut=Data;%default
|
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| 391 | %DataOut.CoordUnit=Calib.CoordUnit;% the output coord unit is set by the calibration parameters
|
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| 392 | X=[];%default output
|
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| 393 | Y=[];
|
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| 394 | Z=0;
|
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| 395 | U=[];
|
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| 396 | V=[];
|
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| 397 | %% transform X,Y coordinates for velocity fields (transform of an image or scalar done in phys_ima)
|
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| 398 | if isfield(Data,'X') &&isfield(Data,'Y')&&~isempty(Data.X) && ~isempty(Data.Y)
|
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[1112] | 399 | [X,Y,Z]=phys_XYZ(Calib,Slice,Data.X,Data.Y,ZIndex);
|
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[1078] | 400 | Dt=1; %default
|
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| 401 | if isfield(Data,'dt')&&~isempty(Data.dt)
|
---|
| 402 | Dt=Data.dt;
|
---|
[40] | 403 | end
|
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[1078] | 404 | if isfield(Data,'Dt')&&~isempty(Data.Dt)
|
---|
| 405 | Dt=Data.Dt;
|
---|
[40] | 406 | end
|
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[1078] | 407 | if isfield(Data,'U')&&isfield(Data,'V')&&~isempty(Data.U) && ~isempty(Data.V)
|
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[1112] | 408 | [XOut_1,YOut_1]=phys_XYZ(Calib,Slice,Data.X-Data.U/2,Data.Y-Data.V/2,ZIndex);
|
---|
| 409 | [XOut_2,YOut_2]=phys_XYZ(Calib,Slice,Data.X+Data.U/2,Data.Y+Data.V/2,ZIndex);
|
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[1078] | 410 | U=(XOut_2-XOut_1)/Dt;
|
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| 411 | V=(YOut_2-YOut_1)/Dt;
|
---|
[40] | 412 | end
|
---|
| 413 | end
|
---|
| 414 |
|
---|
| 415 | %%%%%%%%%%%%%%%%%%%%
|
---|
[1078] | 416 | % tranform gridded field into polar coordiantes on a regular polar grid,
|
---|
| 417 | % transform to phys coordiantes if requested by calibration input
|
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[1112] | 418 | function [A_out,radius,theta]=phys_Ima_polar(A,coord_x,coord_y,CalibIn,SliceIn,ZIndex,origin_xy,radius_offset,angle_offset,angle_scale)
|
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[1078] | 419 | rcorner=[];
|
---|
| 420 | thetacorner=[];
|
---|
[40] | 421 | npx=[];
|
---|
| 422 | npy=[];
|
---|
| 423 | for icell=1:length(A)
|
---|
| 424 | siz=size(A{icell});
|
---|
[1078] | 425 | npx(icell)=siz(2);
|
---|
| 426 | npy(icell)=siz(1);
|
---|
| 427 | x_edge=[linspace(coord_x{icell}(1),coord_x{icell}(end),npx(icell)) coord_x{icell}(end)*ones(1,npy(icell))...
|
---|
| 428 | linspace(coord_x{icell}(end),coord_x{icell}(1),npx(icell)) coord_x{icell}(1)*ones(1,npy(icell))];%x coordinates of the image edge(four sides)
|
---|
| 429 | y_edge=[coord_y{icell}(1)*ones(1,npx(icell)) linspace(coord_y{icell}(1),coord_y{icell}(end),npy(icell))...
|
---|
| 430 | coord_y{icell}(end)*ones(1,npx(icell)) linspace(coord_y{icell}(end),coord_y{icell}(1),npy(icell))];%y coordinates of the image edge(four sides)
|
---|
| 431 |
|
---|
| 432 | % transform edges into phys coordinates if requested
|
---|
| 433 | if ~isempty(CalibIn{icell})
|
---|
[1112] | 434 | [x_edge,y_edge]=phys_XYZ(CalibIn{icell},SliceIn{icell},x_edge,y_edge,ZIndex(icell));% physical coordinates of the image edge
|
---|
[40] | 435 | end
|
---|
[1078] | 436 |
|
---|
| 437 | %transform the corner coordinates into polar ones
|
---|
| 438 | x_edge=x_edge-origin_xy(1);%shift to the origin of the polar coordinates
|
---|
| 439 | y_edge=y_edge-origin_xy(2);%shift to the origin of the polar coordinates
|
---|
| 440 | [theta_edge,r_edge] = cart2pol(x_edge,y_edge);%theta and X are the polar coordinates angle and radius
|
---|
| 441 | if (max(theta_edge)-min(theta_edge))>pi %if the polar origin is inside the image
|
---|
| 442 | r_edge=[0 max(r_edge)];
|
---|
| 443 | theta_edge=[-pi pi];
|
---|
[40] | 444 | end
|
---|
[1078] | 445 | rcorner=[rcorner r_edge];
|
---|
| 446 | thetacorner=[thetacorner theta_edge];
|
---|
[40] | 447 | end
|
---|
[1078] | 448 | nbpoint=max(npx.*npy);
|
---|
| 449 | Min_r=min(rcorner);
|
---|
| 450 | Max_r=max(rcorner);
|
---|
| 451 | Min_theta=min(thetacorner)*angle_scale;
|
---|
| 452 | Max_theta=max(thetacorner)*angle_scale;
|
---|
| 453 | Dr=round_uvmat((Max_r-Min_r)/sqrt(nbpoint));
|
---|
| 454 | Dtheta=round_uvmat((Max_theta-Min_theta)/sqrt(nbpoint));% get a simple mesh for the rescaled angle
|
---|
| 455 | radius=Min_r:Dr:Max_r;% polar coordinates for projections
|
---|
| 456 | theta=Min_theta:Dtheta:Max_theta;
|
---|
[1084] | 457 | %theta=Max_theta:-Dtheta:Min_theta;
|
---|
[1078] | 458 | [Radius,Theta]=meshgrid(radius,theta/angle_scale);%grid in polar coordinates (angles in radians)
|
---|
[40] | 459 | %transform X, Y in cartesian
|
---|
[1078] | 460 | [X,Y] = pol2cart(Theta,Radius);% cartesian coordinates associated to the grid in polar coordinates
|
---|
| 461 | X=X+origin_xy(1);%shift to the origin of the polar coordinates
|
---|
| 462 | Y=Y+origin_xy(2);%shift to the origin of the polar coordinates
|
---|
| 463 | radius=radius-radius_offset;
|
---|
| 464 | theta=theta-angle_offset*angle_scale;
|
---|
| 465 | [np_theta,np_r]=size(Radius);
|
---|
| 466 |
|
---|
| 467 | for icell=1:length(A)
|
---|
| 468 | XIMA=X;
|
---|
| 469 | YIMA=Y;
|
---|
| 470 | if ~isempty(CalibIn{icell})%transform back to pixel if calibration parameters are introduced
|
---|
| 471 | Z=0; %default
|
---|
| 472 | if isfield(CalibIn{icell},'SliceCoord') %.Z= index of plane
|
---|
| 473 | if ZIndex(icell)==0
|
---|
| 474 | ZIndex(icell)=1;
|
---|
| 475 | end
|
---|
| 476 | SliceCoord=CalibIn{icell}.SliceCoord(ZIndex(icell),:);
|
---|
| 477 | Z=SliceCoord(3); %to generalize for non-parallel planes
|
---|
| 478 | if isfield(CalibIn{icell},'SliceAngle')
|
---|
| 479 | norm_plane=angle2normal(CalibIn{icell}.SliceAngle);
|
---|
| 480 | Z=Z-(norm_plane(1)*(X-SliceCoord(1))+norm_plane(2)*(Y-SliceCoord(2)))/norm_plane(3);
|
---|
| 481 | end
|
---|
| 482 | end
|
---|
| 483 | [XIMA,YIMA]=px_XYZ(CalibIn{icell},X,Y,Z);%corresponding image indices for each point in the real space grid
|
---|
| 484 | end
|
---|
| 485 | Dx=(coord_x{icell}(end)-coord_x{icell}(1))/(npx(icell)-1);
|
---|
| 486 | Dy=(coord_y{icell}(end)-coord_y{icell}(1))/(npy(icell)-1);
|
---|
| 487 | indx_ima=1+round((XIMA-coord_x{icell}(1))/Dx);%indices of the initial matrix close to the points of the new grid
|
---|
[1084] | 488 | %indy_ima=1+round((YIMA-coord_y{icell}(1))/Dy);
|
---|
| 489 | indy_ima=1+round((coord_y{icell}(end)-YIMA)/Dy);
|
---|
| 490 | Delta_x=1+(XIMA-coord_x{icell}(1))/Dx-indx_ima;%error in the index discretisation
|
---|
| 491 | Delta_y=1+(coord_y{icell}(end)-YIMA)/Dy-indy_ima;
|
---|
[1078] | 492 | XIMA=reshape(indx_ima,1,[]);%indices reorganized in 'line'
|
---|
| 493 | YIMA=reshape(indy_ima,1,[]);%indices reorganized in 'line'
|
---|
| 494 | flagin=XIMA>=1 & XIMA<=npx(icell) & YIMA >=1 & YIMA<=npy(icell);%flagin=1 inside the original image
|
---|
[164] | 495 | siz=size(A{icell});
|
---|
[1078] | 496 | checkuint8=isa(A{icell},'uint8');%check for image input with 8 bits
|
---|
[1081] | 497 | checkuint16=isa(A{icell},'uint16');%check for image input with 16 bits
|
---|
[1078] | 498 | A{icell}=double(A{icell});
|
---|
[164] | 499 | if numel(siz)==2 %(B/W images)
|
---|
[1078] | 500 | vec_A=reshape(A{icell}(:,:,1),1,[]);%put the original image in line
|
---|
[164] | 501 | ind_in=find(flagin);
|
---|
| 502 | ind_out=find(~flagin);
|
---|
[1084] | 503 | ICOMB=((XIMA-1)*npy(icell)+(npy(icell)+1-YIMA));% indices in vec_A
|
---|
[164] | 504 | ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
|
---|
| 505 | vec_B(ind_in)=vec_A(ICOMB);
|
---|
| 506 | vec_B(ind_out)=zeros(size(ind_out));
|
---|
[1078] | 507 | A_out{icell}=reshape(vec_B,np_theta,np_r);%new image in real coordinates
|
---|
[1084] | 508 | DA_y=circshift(A_out{icell},-1,1)-A_out{icell};% derivative
|
---|
[1078] | 509 | DA_y(end,:)=0;
|
---|
| 510 | DA_x=circshift(A_out{icell},-1,2)-A_out{icell};
|
---|
| 511 | DA_x(:,end)=0;
|
---|
| 512 | A_out{icell}=A_out{icell}+Delta_x.*DA_x+Delta_y.*DA_y;%linear interpolation
|
---|
[164] | 513 | else
|
---|
| 514 | for icolor=1:siz(3)
|
---|
[1078] | 515 | vec_A=reshape(A{icell}(:,:,icolor),1,[]);%put the original image in line
|
---|
| 516 | ind_in=find(flagin);
|
---|
| 517 | ind_out=find(~flagin);
|
---|
| 518 | ICOMB=((XIMA-1)*npy(icell)+(npy(icell)+1-YIMA));
|
---|
| 519 | ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
|
---|
| 520 | vec_B(ind_in)=vec_A(ICOMB);
|
---|
| 521 | vec_B(ind_out)=zeros(size(ind_out));
|
---|
| 522 | A_out{icell}(:,:,icolor)=reshape(vec_B,np_theta,np_r);%new image in real coordinates
|
---|
| 523 | DA_y=circshift(A_out{icell}(:,:,icolor),-1,1)-A_out{icell}(:,:,icolor);
|
---|
| 524 | DA_y(end,:)=0;
|
---|
| 525 | DA_x=circshift(A_out{icell}(:,:,icolor),-1,2)-A_out{icell}(:,:,icolor);
|
---|
| 526 | DA_x(:,end)=0;
|
---|
| 527 | A_out{icell}(:,:,icolor)=A_out{icell}(:,:,icolor)+Delta_x.*DA_x+Delta_y.*DA_y;%linear interpolation
|
---|
[164] | 528 | end
|
---|
| 529 | end
|
---|
[1078] | 530 | if checkuint8
|
---|
| 531 | A_out{icell}=uint8(A_out{icell});
|
---|
| 532 | elseif checkuint16
|
---|
| 533 | A_out{icell}=uint16(A_out{icell});
|
---|
| 534 | end
|
---|
[40] | 535 | end
|
---|
| 536 |
|
---|