[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 | %------------------------------------------------------------------------
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| 4 | %%%% Use the general syntax for transform fields %%%%
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| 5 | % OUTPUT:
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| 6 | % DataOut: output field structure
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| 7 | % .X=radius, .Y=azimuth angle, .U, .V are radial and azimuthal velocity components
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| 8 |
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| 9 | %INPUT:
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| 10 | % DataIn: first input field structure
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| 11 | % XmlData: first input parameter structure,
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| 12 | % .GeometryCalib: substructure of the calibration parameters
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| 13 | % DataIn_1: optional second input field structure
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| 14 | % XmlData_1: optional second input parameter structure
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| 15 | % .GeometryCalib: substructure of the calibration parameters
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[172] | 16 | % transform image coordinates (px) to polar physical coordinates
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[40] | 17 | %[DataOut,DataOut_1]=phys_polar(varargin)
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| 18 | %
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| 19 | % OUTPUT:
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| 20 | % DataOut: structure of modified data field: .X=radius, .Y=azimuth angle, .U, .V are radial and azimuthal velocity components
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| 21 | % DataOut_1: second data field (if two fields are in input)
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| 22 | %
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| 23 | %INPUT:
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| 24 | % Data: structure of input data (like UvData)
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[658] | 25 | % XmlData= structure containing the field .GeometryCalib with calibration parameters
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[40] | 26 | % Data_1: second input field (not mandatory)
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[658] | 27 | % XmlData_1= calibration parameters for the second field
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[574] | 28 | %------------------------------------------------------------------------
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| 29 | function DataOut=phys_polar(DataIn,XmlData,DataIn_1,XmlData_1)
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| 30 | %------------------------------------------------------------------------
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[40] | 31 | Calib{1}=[];
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| 32 | if nargin==2||nargin==4
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[658] | 33 | DataOut=DataIn;%default
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[40] | 34 | DataOut_1=[];%default
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[658] | 35 | if isfield(XmlData,'GeometryCalib')
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| 36 | Calib{1}=XmlData.GeometryCalib;
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[40] | 37 | end
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| 38 | Calib{2}=Calib{1};
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| 39 | else
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| 40 | DataOut.Txt='wrong input: need two or four structures';
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| 41 | end
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| 42 | test_1=0;
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[93] | 43 | if nargin==4% case of two input fields
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[40] | 44 | test_1=1;
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[658] | 45 | DataOut_1=DataIn_1;%default
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| 46 | if isfield(XmlData_1,'GeometryCalib')
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| 47 | Calib{2}=XmlData_1.GeometryCalib;
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[40] | 48 | end
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| 49 | end
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| 50 |
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| 51 | %parameters for polar coordinates (taken from the calibration data of the first field)
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| 52 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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| 53 | origin_xy=[0 0];%center for the polar coordinates in the original x,y coordinates
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[658] | 54 | if isfield(XmlData,'PolarCentre') && isnumeric(XmlData.PolarCentre)
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| 55 | if isequal(length(XmlData.PolarCentre),2);
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| 56 | origin_xy= XmlData.PolarCentre;
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[40] | 57 | end
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| 58 | end
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| 59 | radius_offset=0;%reference radius used to offset the radial coordinate r
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| 60 | angle_offset=0; %reference angle used as new origin of the polar angle (= axis Ox by default)
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[658] | 61 | if isfield(XmlData,'PolarReferenceRadius') && isnumeric(XmlData.PolarReferenceRadius)
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| 62 | radius_offset=XmlData.PolarReferenceRadius;
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[40] | 63 | end
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| 64 | if radius_offset > 0
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| 65 | angle_scale=radius_offset; %the azimuth is rescale in terms of the length along the reference radius
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| 66 | else
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| 67 | angle_scale=180/pi; %polar angle in degrees
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| 68 | end
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[658] | 69 | if isfield(XmlData,'PolarReferenceAngle') && isnumeric(XmlData.PolarReferenceAngle)
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| 70 | angle_offset=XmlData.PolarReferenceAngle; %offset angle (in unit of the final angle, degrees or arc length along the reference radius))
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[40] | 71 | end
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| 72 | % new x coordinate = radius-radius_offset;
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| 73 | % new y coordinate = theta*angle_scale-angle_offset
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| 74 |
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| 75 | %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
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| 76 |
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| 77 | iscalar=0;
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[93] | 78 | %transform first field to cartesian phys coordiantes
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[40] | 79 | if ~isempty(Calib{1})
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| 80 | DataOut=phys_1(Data,Calib{1},origin_xy,radius_offset,angle_offset,angle_scale);
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| 81 | %case of images or scalar
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| 82 | if isfield(Data,'A')&isfield(Data,'AX')&~isempty(Data.AX) & isfield(Data,'AY')&...
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| 83 | ~isempty(Data.AY)&length(Data.A)>1
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| 84 | iscalar=1;
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| 85 | A{1}=Data.A;
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| 86 | end
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| 87 | %transform of X,Y coordinates for vector fields
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| 88 | if isfield(Data,'ZIndex')&~isempty(Data.ZIndex)
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| 89 | ZIndex=Data.ZIndex;
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| 90 | else
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| 91 | ZIndex=0;
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| 92 | end
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| 93 | end
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[567] | 94 |
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[93] | 95 | %transform second field (if exists) to cartesian phys coordiantes
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[40] | 96 | if test_1
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| 97 | DataOut_1=phys_1(Data_1,Calib{2},origin_xy,radius_offset,angle_offset,angle_scale);
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| 98 | if isfield(Data_1,'A')&isfield(Data_1,'AX')&~isempty(Data_1.AX) & isfield(Data_1,'AY')&...
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| 99 | ~isempty(Data_1.AY)&length(Data_1.A)>1
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| 100 | iscalar=iscalar+1;
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| 101 | Calib{iscalar}=Calib{2};
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| 102 | A{iscalar}=Data_1.A;
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| 103 | if isfield(Data_1,'ZIndex')&~isequal(Data_1.ZIndex,ZIndex)
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| 104 | DataOut.Txt='inconsistent plane indexes in the two input fields';
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| 105 | end
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| 106 | if iscalar==1% case for which only the second field is a scalar
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[164] | 107 | [A,AX,AY]=phys_Ima_polar(A,Calib,ZIndex,origin_xy,radius_offset,angle_offset,angle_scale);
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[40] | 108 | DataOut_1.A=A{1};
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| 109 | DataOut_1.AX=AX;
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| 110 | DataOut_1.AY=AY;
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| 111 | return
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| 112 | end
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| 113 | end
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| 114 | end
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| 115 | if iscalar~=0
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[164] | 116 | [A,AX,AY]=phys_Ima_polar(A,Calib,ZIndex,origin_xy,radius_offset,angle_offset,angle_scale);%
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[40] | 117 | DataOut.A=A{1};
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| 118 | DataOut.AX=AX;
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| 119 | DataOut.AY=AY;
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| 120 | if iscalar==2
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| 121 | DataOut_1.A=A{2};
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| 122 | DataOut_1.AX=AX;
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| 123 | DataOut_1.AY=AY;
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| 124 | end
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| 125 | end
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| 126 |
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[161] | 127 |
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| 128 |
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| 129 |
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[40] | 130 | %------------------------------------------------
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| 131 | function DataOut=phys_1(Data,Calib,origin_xy,radius_offset,angle_offset,angle_scale)
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| 132 |
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| 133 | DataOut=Data;
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[167] | 134 | % DataOut.CoordUnit=Calib.CoordUnit; %put flag for physical coordinates
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[161] | 135 | if isfield(Calib,'SliceCoord')
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| 136 | DataOut.PlaneCoord=Calib.SliceCoord;%to generalise for any plane
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[40] | 137 | end
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[161] | 138 |
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| 139 | if isfield(Data,'CoordUnit')%&& isequal(Data.CoordType,'px')&& ~isempty(Calib)
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| 140 | if isfield(Calib,'CoordUnit')
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| 141 | DataOut.CoordUnit=Calib.CoordUnit;
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| 142 | else
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| 143 | DataOut.CoordUnit='cm'; %default
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[40] | 144 | end
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[161] | 145 | DataOut.TimeUnit='s';
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[40] | 146 | %transform of X,Y coordinates for vector fields
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[161] | 147 | if isfield(Data,'ZIndex') && ~isempty(Data.ZIndex)&&~isnan(Data.ZIndex)
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[40] | 148 | Z=Data.ZIndex;
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| 149 | else
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| 150 | Z=0;
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| 151 | end
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| 152 | if isfield(Data,'X') &isfield(Data,'Y')&~isempty(Data.X) & ~isempty(Data.Y)
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| 153 | [DataOut.X,DataOut.Y,DataOut.Z]=phys_XYZ(Calib,Data.X,Data.Y,Z); %transform from pixels to physical
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| 154 | DataOut.X=DataOut.X-origin_xy(1);%origin of coordinates at the tank center
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| 155 | DataOut.Y=DataOut.Y-origin_xy(2);%origin of coordinates at the tank center
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| 156 | [theta,DataOut.X] = cart2pol(DataOut.X,DataOut.Y);%theta and X are the polar coordinates angle and radius
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| 157 | %shift and renormalize the polar coordinates
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| 158 | DataOut.X=DataOut.X-radius_offset;%
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| 159 | DataOut.Y=theta*angle_scale-angle_offset;% normalized angle: distance along reference radius
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| 160 | %transform velocity field if exists
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| 161 | if isfield(Data,'U')&isfield(Data,'V')&~isempty(Data.U) & ~isempty(Data.V)& isfield(Data,'dt')
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| 162 | if ~isempty(Data.dt)
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| 163 | [XOut_1,YOut_1]=phys_XYZ(Calib,Data.X-Data.U/2,Data.Y-Data.V/2,Z);
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| 164 | [XOut_2,YOut_2]=phys_XYZ(Calib,Data.X+Data.U/2,Data.Y+Data.V/2,Z);
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| 165 | UX=(XOut_2-XOut_1)/Data.dt;
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| 166 | VY=(YOut_2-YOut_1)/Data.dt;
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| 167 | %transform u,v into polar coordiantes
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| 168 | DataOut.U=UX.*cos(theta)+VY.*sin(theta);%radial velocity
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| 169 | DataOut.V=(-UX.*sin(theta)+VY.*cos(theta));%./(DataOut.X)%+radius_ref);%angular velocity calculated
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| 170 | %shift and renormalize the angular velocity
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| 171 | end
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| 172 | end
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[93] | 173 | %transform of spatial derivatives
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| 174 | if isfield(Data,'X') && ~isempty(Data.X) && isfield(Data,'DjUi') && ~isempty(Data.DjUi)...
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| 175 | && isfield(Data,'dt')
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| 176 | if ~isempty(Data.dt)
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| 177 | % estimate the Jacobian matrix DXpx/DXphys
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| 178 | for ip=1:length(Data.X)
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| 179 | [Xp1,Yp1]=phys_XYZ(Calib,Data.X(ip)+0.5,Data.Y(ip),Z);
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| 180 | [Xm1,Ym1]=phys_XYZ(Calib,Data.X(ip)-0.5,Data.Y(ip),Z);
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| 181 | [Xp2,Yp2]=phys_XYZ(Calib,Data.X(ip),Data.Y(ip)+0.5,Z);
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| 182 | [Xm2,Ym2]=phys_XYZ(Calib,Data.X(ip),Data.Y(ip)-0.5,Z);
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| 183 | %Jacobian matrix DXpphys/DXpx
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| 184 | DjXi(1,1)=(Xp1-Xm1);
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| 185 | DjXi(2,1)=(Yp1-Ym1);
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| 186 | DjXi(1,2)=(Xp2-Xm2);
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| 187 | DjXi(2,2)=(Yp2-Ym2);
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| 188 | DjUi(:,:)=Data.DjUi(ip,:,:);
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| 189 | DjUi=(DjXi*DjUi')/DjXi;% =J-1*M*J , curvature effects (derivatives of J) neglected
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| 190 | DataOut.DjUi(ip,:,:)=DjUi';
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| 191 | end
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| 192 | DataOut.DjUi = DataOut.DjUi/Data.dt; % min(Data.DjUi(:,1,1))=DUDX
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| 193 | end
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| 194 | end
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[40] | 195 | end
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| 196 | end
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| 197 |
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[164] | 198 |
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[40] | 199 | %%%%%%%%%%%%%%%%%%%%
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[164] | 200 | function [A_out,Rangx,Rangy]=phys_Ima_polar(A,CalibIn,ZIndex,origin_xy,radius_offset,angle_offset,angle_scale)
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[40] | 201 | xcorner=[];
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| 202 | ycorner=[];
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| 203 | npx=[];
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| 204 | npy=[];
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| 205 | for icell=1:length(A)
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| 206 | siz=size(A{icell});
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| 207 | npx=[npx siz(2)];
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| 208 | npy=[npy siz(1)];
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| 209 | zphys=0; %default
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| 210 | if isfield(CalibIn{icell},'SliceCoord') %.Z= index of plane
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| 211 | SliceCoord=CalibIn{icell}.SliceCoord(ZIndex,:);
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| 212 | zphys=SliceCoord(3); %to generalize for non-parallel planes
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| 213 | end
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| 214 | xima=[0.5 siz(2)-0.5 0.5 siz(2)-0.5];%image coordiantes of corners
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| 215 | yima=[0.5 0.5 siz(1)-0.5 siz(1)-0.5];
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| 216 | [xcorner_new,ycorner_new]=phys_XYZ(CalibIn{icell},xima,yima,ZIndex);%corresponding physical coordinates
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| 217 | %transform the corner coordinates into polar ones
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| 218 | xcorner_new=xcorner_new-origin_xy(1);%shift to the origin of the polar coordinates
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| 219 | ycorner_new=ycorner_new-origin_xy(2);%shift to the origin of the polar coordinates
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| 220 | [theta,xcorner_new] = cart2pol(xcorner_new,ycorner_new);%theta and X are the polar coordinates angle and radius
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| 221 | if (max(theta)-min(theta))>pi %if the polar origin is inside the image
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| 222 | xcorner_new=[0 max(xcorner_new)];
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| 223 | theta=[-pi pi];
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| 224 | end
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| 225 | %shift and renormalize the polar coordinates
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| 226 | xcorner_new=xcorner_new-radius_offset;%
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| 227 | ycorner_new=theta*angle_scale-angle_offset;% normalized angle: distance along reference radius
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| 228 | xcorner=[xcorner xcorner_new];
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| 229 | ycorner=[ycorner ycorner_new];
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| 230 | end
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| 231 | Rangx(1)=min(xcorner);
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| 232 | Rangx(2)=max(xcorner);
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| 233 | Rangy(2)=min(ycorner);
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| 234 | Rangy(1)=max(ycorner);
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| 235 | % test_multi=(max(npx)~=min(npx)) | (max(npy)~=min(npy));
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| 236 | npx=max(npx);
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| 237 | npy=max(npy);
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| 238 | x=linspace(Rangx(1),Rangx(2),npx);
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| 239 | y=linspace(Rangy(1),Rangy(2),npy);
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| 240 | [X,Y]=meshgrid(x,y);%grid in physical coordinates
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| 241 | %transform X, Y in cartesian
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| 242 | X=X+radius_offset;%
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| 243 | Y=(Y+angle_offset)/angle_scale;% normalized angle: distance along reference radius
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| 244 | [X,Y] = pol2cart(Y,X);
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| 245 | X=X+origin_xy(1);%shift to the origin of the polar coordinates
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| 246 | Y=Y+origin_xy(2);%shift to the origin of the polar coordinates
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| 247 | for icell=1:length(A)
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[164] | 248 | siz=size(A{icell});
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[40] | 249 | [XIMA,YIMA]=px_XYZ(CalibIn{icell},X,Y,zphys);%corresponding image indices for each point in the real space grid
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| 250 | XIMA=reshape(round(XIMA),1,npx*npy);%indices reorganized in 'line'
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| 251 | YIMA=reshape(round(YIMA),1,npx*npy);
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| 252 | flagin=XIMA>=1 & XIMA<=npx & YIMA >=1 & YIMA<=npy;%flagin=1 inside the original image
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[164] | 253 | if numel(siz)==2 %(B/W images)
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| 254 | vec_A=reshape(A{icell}(:,:,1),1,npx*npy);%put the original image in line
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| 255 | ind_in=find(flagin);
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| 256 | ind_out=find(~flagin);
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| 257 | ICOMB=((XIMA-1)*npy+(npy+1-YIMA));
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| 258 | ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
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| 259 | vec_B(ind_in)=vec_A(ICOMB);
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| 260 | vec_B(ind_out)=zeros(size(ind_out));
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| 261 | A_out{icell}=reshape(vec_B,npy,npx);%new image in real coordinates
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| 262 | else
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| 263 | for icolor=1:siz(3)
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| 264 | vec_A=reshape(A{icell}(:,:,icolor),1,npx*npy);%put the original image in line
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| 265 | ind_in=find(flagin);
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| 266 | ind_out=find(~flagin);
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| 267 | ICOMB=((XIMA-1)*npy+(npy+1-YIMA));
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| 268 | ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
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| 269 | vec_B(ind_in)=vec_A(ICOMB);
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| 270 | vec_B(ind_out)=zeros(size(ind_out));
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| 271 | A_out{icell}(:,:,icolor)=reshape(vec_B,npy,npx);%new image in real coordinates
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| 272 | end
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| 273 | end
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[40] | 274 | end
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| 275 |
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