[404] | 1 |
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| 2 |
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[124] | 3 | %'calc_field': defines fields (velocity, vort, div...) from civx data and calculate them
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[8] | 4 | %---------------------------------------------------------------------
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[399] | 5 | % [DataOut,errormsg]=calc_field(FieldList,DataIn,Coord_interp)
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[8] | 6 | %
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[124] | 7 | % OUTPUT:
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| 8 | % Scal: matlab vector representing the scalar values (length nbvec defined by var_read)
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[123] | 9 | % if no input, Scal=list of programmed scalar names (to put in menus)
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| 10 | % if only the field name is put as input, vec_A=type of scalar, which can be:
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| 11 | % 'discrete': related to the individual velocity vectors, not interpolated by patch
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[8] | 12 | % 'vel': scalar calculated solely from velocity components
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[124] | 13 | % 'der': needs spatial derivatives
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[8] | 14 | % 'var': the scalar name directly corresponds to a field name in the netcdf files
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| 15 | % error: error flag
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[89] | 16 | % error = 0; OK
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| 17 | % error = 1; the prescribed scalar cannot be read or calculated from available fields
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| 18 | %
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[8] | 19 | % INPUT:
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[399] | 20 | % FieldList: cell array of strings representing the name(s) of the field(s) to calculate
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[8] | 21 | % DataIn: structure representing the field, as defined in check_field_srtructure.m
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[399] | 22 | % Coord_interp(:,nb_coord) optional set of coordinates to interpolate the field (use with thin plate shell)
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[89] | 23 | %
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[8] | 24 | % FUNCTION related
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[124] | 25 | % varname_generator.m: determines the field names to read in the netcdf
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| 26 | % file, depending on the scalar
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[8] | 27 |
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[399] | 28 | function [DataOut,errormsg]=calc_field(FieldList,DataIn,Coord_interp)
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[8] | 29 |
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| 30 | %list of defined scalars to display in menus (in addition to 'ima_cor').
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[124] | 31 | % a type is associated to each scalar:
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[8] | 32 | % 'discrete': related to the individual velocity vectors, not interpolated by patch
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[124] | 33 | % 'vel': calculated from velocity components, continuous field (interpolated with velocity)
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| 34 | % 'der': needs spatial derivatives
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[8] | 35 | % 'var': the scalar name corresponds to a field name in the netcdf files
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| 36 | % a specific variable name for civ1 and civ2 fields are also associated, if
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[123] | 37 | % the scalar is calculated from other fields, as explicited below
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| 38 |
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[404] | 39 | %% list of field options implemented
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| 40 | FieldOptions={'velocity';...%image correlation corresponding to a vel vector
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[124] | 41 | 'ima_cor';...%image correlation corresponding to a vel vector
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| 42 | 'norm_vel';...%norm of the velocity
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| 43 | 'vort';...%vorticity
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| 44 | 'div';...%divergence
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| 45 | 'strain';...%rate of strain
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| 46 | 'u';... %u velocity component
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| 47 | 'v';... %v velocity component
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| 48 | 'w';... %w velocity component
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| 49 | 'w_normal';... %w velocity component normal to the plane
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| 50 | 'error'}; %error associated to a vector (for stereo or patch)
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[8] | 51 | errormsg=[]; %default error message
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[399] | 52 | if ~exist('FieldList','var')
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[404] | 53 | DataOut=FieldOptions;% gives the list of possible field inputs in the absence of input
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| 54 | return
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| 55 | end
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| 56 |
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| 57 | %% check input
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| 58 | if ~exist('DataIn','var')
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| 59 | DataIn=[];
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| 60 | end
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| 61 | if ischar(FieldList)
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| 62 | FieldList={FieldList};%convert a string input to a cell with one string element
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| 63 | end
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| 64 | check_grid=0;
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| 65 | check_der=0;
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| 66 | check_calc=ones(size(FieldList));
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| 67 | for ilist=1:length(FieldList)
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| 68 | switch FieldList{ilist}
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[491] | 69 | case {'u','v','velocity','norm_vel','ima_cor'}
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[404] | 70 | check_grid=1;% needs a regular grid
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| 71 | case{'vort','div','strain'}% needs spatial derivatives spatial derivatives
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| 72 | check_der=1;
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[491] | 73 | % case {'velocity','norm_vel','ima_cor'};
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[404] | 74 | otherwise
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| 75 | check_calc(ilist)=0;
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| 76 | end
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| 77 | end
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| 78 | FieldList=FieldList(check_calc==1);
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[405] | 79 | % if isempty(FieldList)
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| 80 | % DataOut=DataIn;
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| 81 | % return
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| 82 | % end
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[404] | 83 | if isfield(DataIn,'Z')&& isequal(size(DataIn.Z),size(DataIn.X))
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| 84 | nbcoord=3;
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[8] | 85 | else
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[404] | 86 | nbcoord=2;
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| 87 | end
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| 88 | ListVarName={};
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| 89 | ValueList={};
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| 90 | RoleList={};
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| 91 | units_cell={};
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| 92 |
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| 93 | %% interpolation with new civ data
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| 94 | if isfield(DataIn,'SubRange') && isfield(DataIn,'Coord_tps') && (exist('Coord_interp','var') || check_grid ||check_der)
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[406] | 95 | %reproduce global attributes
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| 96 | DataOut.ListGlobalAttribute=DataIn.ListGlobalAttribute;
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[404] | 97 | for ilist=1:numel(DataOut.ListGlobalAttribute)
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| 98 | DataOut.(DataOut.ListGlobalAttribute{ilist})=DataIn.(DataIn.ListGlobalAttribute{ilist});
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[8] | 99 | end
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[406] | 100 |
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[405] | 101 | %create a default grid if needed
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| 102 | if ~exist('Coord_interp','var')
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[406] | 103 | XMax=max(max(DataIn.SubRange(1,:,:)));% extrema of the coordinates
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| 104 | YMax=max(max(DataIn.SubRange(2,:,:)));
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| 105 | XMin=min(min(DataIn.SubRange(1,:,:)));
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| 106 | YMin=min(min(DataIn.SubRange(2,:,:)));
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[405] | 107 | if ~isfield(DataIn,'Mesh')
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| 108 | DataIn.Mesh=sqrt(2*(XMax-XMin)*(YMax-YMin)/numel(DataIn.Coord_tps));
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| 109 | % adjust the mesh to a value 1, 2 , 5 *10^n
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| 110 | ord=10^(floor(log10(DataIn.Mesh)));%order of magnitude
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| 111 | if DataIn.Mesh/ord>=5
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| 112 | DataIn.Mesh=5*ord;
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| 113 | elseif DataIn.Mesh/ord>=2
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| 114 | DataIn.Mesh=2*ord;
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| 115 | else
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| 116 | DataIn.Mesh=ord;
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| 117 | end
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| 118 | end
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[501] | 119 | coord_x=XMin:DataIn.Mesh:XMax;% increase the recommanded mesh to visualisation
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[405] | 120 | coord_y=YMin:DataIn.Mesh:YMax;
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[491] | 121 | % npx=length(coord_x);
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| 122 | % npy=length(coord_y);
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[406] | 123 | DataOut.coord_x=[XMin XMax];
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| 124 | DataOut.coord_y=[YMin YMax];
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[405] | 125 | [XI,YI]=meshgrid(coord_x,coord_y);
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[491] | 126 | % XI=reshape(XI,[],1);
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| 127 | % YI=reshape(YI,[],1);
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| 128 | Coord_interp=cat(3,XI,YI);%[XI YI];
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[405] | 129 | end
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[491] | 130 | npx=size(Coord_interp,2);
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| 131 | npy=size(Coord_interp,1);
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| 132 | Coord_interp=reshape(Coord_interp,npx*npy,size(Coord_interp,3));
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| 133 | % npy=length(coord_y);
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[406] | 134 | %initialise output
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[404] | 135 | nb_sites=size(Coord_interp,1);
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| 136 | nb_coord=size(Coord_interp,2);
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[406] | 137 | nbval=zeros(nb_sites,1);
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| 138 | NbSubDomain=size(DataIn.SubRange,3);
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| 139 | DataOut.ListVarName={'coord_y','coord_x'};
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| 140 | DataOut.VarDimName={{'coord_y'},{'coord_x'}};
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| 141 | DataOut.VarAttribute{1}=[];
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| 142 | DataOut.VarAttribute{2}=[];
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[404] | 143 | for ilist=1:length(FieldList)
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| 144 | switch FieldList{ilist}
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| 145 | case 'velocity'
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| 146 | DataOut.U=zeros(nb_sites,1);
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| 147 | DataOut.V=zeros(nb_sites,1);
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| 148 | otherwise
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| 149 | DataOut.(FieldList{ilist})=zeros(nb_sites,1);
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[389] | 150 | end
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[404] | 151 | end
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[406] | 152 |
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| 153 | % interpolate data in each subdomain
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[404] | 154 | for isub=1:NbSubDomain
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| 155 | nbvec_sub=DataIn.NbSites(isub);
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| 156 | check_range=(Coord_interp >=ones(nb_sites,1)*DataIn.SubRange(:,1,isub)' & Coord_interp<=ones(nb_sites,1)*DataIn.SubRange(:,2,isub)');
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| 157 | ind_sel=find(sum(check_range,2)==nb_coord);
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| 158 | %rho smoothing parameter
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| 159 | % epoints = Coord_interp(ind_sel) ;% coordinates of interpolation sites
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| 160 | % ctrs=DataIn.Coord_tps(1:nbvec_sub,:,isub);%(=initial points) ctrs
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| 161 | nbval(ind_sel)=nbval(ind_sel)+1;% records the number of values for eacn interpolation point (in case of subdomain overlap)
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[405] | 162 | if check_grid
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[404] | 163 | EM = tps_eval(Coord_interp(ind_sel,:),DataIn.Coord_tps(1:nbvec_sub,:,isub));%kernels for calculating the velocity from tps 'sources'
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[246] | 164 | end
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[404] | 165 | if check_der
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| 166 | [EMDX,EMDY] = tps_eval_dxy(Coord_interp(ind_sel,:),DataIn.Coord_tps(1:nbvec_sub,:,isub));%kernels for calculating the spatial derivatives from tps 'sources'
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| 167 | end
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[412] | 168 | ListVar={};
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[399] | 169 | for ilist=1:length(FieldList)
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[412] | 170 | var_count=numel(ListVar);
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[404] | 171 | switch FieldList{ilist}
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| 172 | case 'velocity'
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[412] | 173 | ListVar=[ListVar {'U', 'V'}];
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[411] | 174 | VarAttribute{var_count+1}.Role='vector_x';
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| 175 | VarAttribute{var_count+2}.Role='vector_y';
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[404] | 176 | DataOut.U(ind_sel)=DataOut.U(ind_sel)+EM *DataIn.U_tps(1:nbvec_sub+3,isub);
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| 177 | DataOut.V(ind_sel)=DataOut.V(ind_sel)+EM *DataIn.V_tps(1:nbvec_sub+3,isub);
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| 178 | case 'u'
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[412] | 179 | ListVar=[ListVar {'u'}];
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[411] | 180 | VarAttribute{var_count+1}.Role='scalar';
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[406] | 181 | DataOut.u(ind_sel)=DataOut.u(ind_sel)+EM *DataIn.U_tps(1:nbvec_sub+3,isub);
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[404] | 182 | case 'v'
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[412] | 183 | ListVar=[ListVar {'v'}];
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[411] | 184 | VarAttribute{var_count+1}.Role='scalar';
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[406] | 185 | DataOut.v(ind_sel)=DataOut.v(ind_sel)+EM *DataIn.V_tps(1:nbvec_sub+3,isub);
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[405] | 186 | case 'norm_vel'
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[412] | 187 | ListVar=[ListVar {'norm_vel'}];
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[411] | 188 | VarAttribute{var_count+1}.Role='scalar';
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| 189 | U=DataOut.U(ind_sel)+EM *DataIn.U_tps(1:nbvec_sub+3,isub);
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[404] | 190 | V=DataOut.V(ind_sel)+EM *DataIn.V_tps(1:nbvec_sub+3,isub);
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| 191 | DataOut.norm_vel(ind_sel)=sqrt(U.*U+V.*V);
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| 192 | case 'vort'
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[412] | 193 | ListVar=[ListVar {'vort'}];
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[411] | 194 | VarAttribute{var_count+1}.Role='scalar';
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| 195 | DataOut.vort(ind_sel)=DataOut.vort(ind_sel)-EMDY *DataIn.U_tps(1:nbvec_sub+3,isub)+EMDX *DataIn.V_tps(1:nbvec_sub+3,isub);
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[404] | 196 | case 'div'
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[412] | 197 | ListVar=[ListVar {'div'}];
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[411] | 198 | VarAttribute{var_count+1}.Role='scalar';
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[404] | 199 | DataOut.div(ind_sel)=DataOut.div(ind_sel)+EMDX*DataIn.U_tps(1:nbvec_sub+3,isub)+EMDY *DataIn.V_tps(1:nbvec_sub+3,isub);
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| 200 | case 'strain'
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[412] | 201 | ListVar=[ListVar {'strain'}];
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[411] | 202 | VarAttribute{var_count+1}.Role='scalar';
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[404] | 203 | DataOut.strain(ind_sel)=DataOut.strain(ind_sel)+EMDY*DataIn.U_tps(1:nbvec_sub+3,isub)+EMDX *DataIn.V_tps(1:nbvec_sub+3,isub);
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[246] | 204 | end
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| 205 | end
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[404] | 206 | end
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[411] | 207 | DataOut.FF=nbval==0; %put errorflag to 1 for points outside the interpolation rang
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[412] | 208 | nbval(nbval==0)=1;% to avoid division by zero for averaging
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[411] | 209 | if isempty(find(strcmp('FF',DataOut.ListVarName),1))% if FF is not already listed
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| 210 | DataOut.ListVarName=[DataOut.ListVarName {'FF'}];
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| 211 | DataOut.VarDimName=[DataOut.VarDimName {{'coord_y','coord_x'}}];
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| 212 | DataOut.VarAttribute{length(DataOut.ListVarName)}.Role='errorflag';
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| 213 | end
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[412] | 214 | DataOut.ListVarName=[DataOut.ListVarName ListVar];
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| 215 | for ifield=1:numel(ListVar)
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[411] | 216 | VarDimName{ifield}={'coord_y','coord_x'};
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[412] | 217 | DataOut.(ListVar{ifield})=DataOut.(ListVar{ifield})./nbval;
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| 218 | DataOut.(ListVar{ifield})=reshape(DataOut.(ListVar{ifield}),npy,npx);
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[411] | 219 | end
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| 220 | DataOut.FF=reshape(DataOut.FF,npy,npx);
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| 221 | DataOut.VarDimName=[DataOut.VarDimName VarDimName];
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| 222 | DataOut.VarAttribute=[DataOut.VarAttribute VarAttribute];
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[404] | 223 | else
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| 224 |
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| 225 | %% civx data
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| 226 | DataOut=DataIn;
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| 227 | for ilist=1:length(FieldList)
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| 228 | if ~isempty(FieldList{ilist})
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| 229 | [VarName,Value,Role,units]=feval(FieldList{ilist},DataIn);%calculate field with appropriate function named FieldList{ilist}
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| 230 | ListVarName=[ListVarName VarName];
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| 231 | ValueList=[ValueList Value];
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| 232 | RoleList=[RoleList Role];
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| 233 | units_cell=[units_cell units];
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[246] | 234 | end
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[124] | 235 | end
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[404] | 236 | %erase previous data (except coordinates)
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| 237 | for ivar=nbcoord+1:length(DataOut.ListVarName)
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| 238 | VarName=DataOut.ListVarName{ivar};
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| 239 | DataOut=rmfield(DataOut,VarName);
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| 240 | end
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| 241 | DataOut.ListVarName=DataOut.ListVarName(1:nbcoord);
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| 242 | if isfield(DataOut,'VarDimName')
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| 243 | DataOut.VarDimName=DataOut.VarDimName(1:nbcoord);
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| 244 | else
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| 245 | errormsg='element .VarDimName missing in input data';
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| 246 | return
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| 247 | end
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| 248 | DataOut.VarAttribute=DataOut.VarAttribute(1:nbcoord);
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| 249 | %append new data
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| 250 | DataOut.ListVarName=[DataOut.ListVarName ListVarName];
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| 251 | for ivar=1:length(ListVarName)
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| 252 | DataOut.VarDimName{nbcoord+ivar}=DataOut.VarDimName{1};
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| 253 | DataOut.VarAttribute{nbcoord+ivar}.Role=RoleList{ivar};
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| 254 | DataOut.VarAttribute{nbcoord+ivar}.units=units_cell{ivar};
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| 255 | DataOut.(ListVarName{ivar})=ValueList{ivar};
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| 256 | end
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[8] | 257 | end
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| 258 |
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[246] | 259 |
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[404] | 260 |
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[8] | 261 | %%%%%%%%%%%%% velocity fieldn%%%%%%%%%%%%%%%%%%%%
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| 262 | function [VarName,ValCell,Role,units_cell]=velocity(DataIn)
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| 263 | VarName={};
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| 264 | ValCell={};
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| 265 | Role={};
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| 266 | units_cell={};
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| 267 | if isfield(DataIn,'CoordUnit') && isfield(DataIn,'TimeUnit')
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| 268 | units=[DataIn.CoordUnit '/' DataIn.TimeUnit];
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| 269 | else
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| 270 | units='pixel';
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| 271 | end
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| 272 | if isfield(DataIn,'U')
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| 273 | VarName=[VarName {'U'}];
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| 274 | ValCell=[ValCell {DataIn.U}];
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| 275 | Role=[Role {'vector_x'}];
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| 276 | units_cell=[units_cell {units}];
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| 277 | end
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| 278 | if isfield(DataIn,'V')
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| 279 | VarName=[VarName {'V'}];
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| 280 | ValCell=[ValCell {DataIn.V}];
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[124] | 281 | Role=[Role {'vector_y'}];
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[8] | 282 | units_cell=[units_cell {units}];
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| 283 | end
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| 284 | if isfield(DataIn,'W')
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| 285 | VarName=[VarName {'W'}];
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| 286 | ValCell=[ValCell {DataIn.W}];
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| 287 | Role=[Role {'vector_z'}];
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| 288 | units_cell=[units_cell {units}];
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| 289 | end
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| 290 | if isfield(DataIn,'F')
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| 291 | VarName=[VarName {'F'}];
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| 292 | ValCell=[ValCell {DataIn.F}];
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| 293 | Role=[Role {'warnflag'}];
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| 294 | units_cell=[units_cell {[]}];
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| 295 | end
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| 296 | if isfield(DataIn,'FF')
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| 297 | VarName=[VarName,{'FF'}];
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| 298 | ValCell=[ValCell {DataIn.FF}];
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| 299 | Role=[Role {'errorflag'}];
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| 300 | units_cell=[units_cell {[]}];
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| 301 | end
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| 302 |
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| 303 | %%%%%%%%%%%%% ima cor%%%%%%%%%%%%%%%%%%%%
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| 304 | function [VarName,ValCell,Role,units]=ima_cor(DataIn)
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| 305 | VarName={};
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| 306 | ValCell={};
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| 307 | Role={};
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| 308 | units={};
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| 309 | if isfield(DataIn,'C')
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| 310 | VarName{1}='C';
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| 311 | ValCell{1}=DataIn.C;
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| 312 | Role={'ancillary'};
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| 313 | units={[]};
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| 314 | end
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| 315 |
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| 316 | %%%%%%%%%%%%% norm_vec %%%%%%%%%%%%%%%%%%%%
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| 317 | function [VarName,ValCell,Role,units]=norm_vel(DataIn)
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| 318 | VarName={};
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| 319 | ValCell={};
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| 320 | Role={};
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| 321 | units={};
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| 322 | if isfield(DataIn,'U') && isfield(DataIn,'V')
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| 323 | VarName{1}='norm_vel';
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[124] | 324 | ValCell{1}=DataIn.U.*DataIn.U+ DataIn.V.*DataIn.V;
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| 325 | if isfield(DataIn,'W') && isequal(size(DataIn.W),size(DataIn.U))
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| 326 | ValCell{1}=ValCell{1}+DataIn.W.*DataIn.W;
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| 327 | end
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| 328 | ValCell{1}=sqrt(ValCell{1});
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| 329 | Role{1}='scalar';
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| 330 | if isfield(DataIn,'CoordUnit') && isfield(DataIn,'TimeUnit')
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[8] | 331 | units={[DataIn.CoordUnit '/' DataIn.TimeUnit]};
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[124] | 332 | else
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[8] | 333 | units={'pixel'};
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[124] | 334 | end
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| 335 | end
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[8] | 336 |
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| 337 |
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| 338 |
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| 339 | %%%%%%%%%%%%% vorticity%%%%%%%%%%%%%%%%%%%%
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| 340 | function [VarName,ValCell,Role,units]=vort(DataIn)
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| 341 | VarName={};
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| 342 | ValCell={};
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| 343 | Role={};
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| 344 | units={};
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| 345 | if isfield(DataIn,'DjUi')
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| 346 | VarName{1}='vort';
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| 347 | ValCell{1}=DataIn.DjUi(:,1,2)-DataIn.DjUi(:,2,1); %vorticity
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| 348 | siz=size(ValCell{1});
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| 349 | ValCell{1}=reshape(ValCell{1},siz(1),1);
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| 350 | Role{1}='scalar';
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| 351 | if isfield(DataIn,'TimeUnit')
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| 352 | units={[DataIn.TimeUnit '-1']};
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| 353 | else
|
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| 354 | units={[]};
|
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| 355 | end
|
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[124] | 356 | end
|
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[8] | 357 |
|
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| 358 | %%%%%%%%%%%%% divergence%%%%%%%%%%%%%%%%%%%%
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| 359 | function [VarName,ValCell,Role,units]=div(DataIn)
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| 360 | VarName={};
|
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| 361 | ValCell={};
|
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| 362 | Role={};
|
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| 363 | units={};
|
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| 364 | if isfield(DataIn,'DjUi')
|
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| 365 | VarName{1}='div';
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| 366 | ValCell{1}=DataIn.DjUi(:,1,1)+DataIn.DjUi(:,2,2); %DUDX+DVDY
|
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| 367 | siz=size(ValCell{1});
|
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| 368 | ValCell{1}=reshape(ValCell{1},siz(1),1);
|
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| 369 | Role{1}='scalar';
|
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| 370 | if isfield(DataIn,'TimeUnit')
|
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| 371 | units={[DataIn.TimeUnit '-1']};
|
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| 372 | else
|
---|
| 373 | units={[]};
|
---|
| 374 | end
|
---|
[124] | 375 | end
|
---|
[8] | 376 |
|
---|
| 377 | %%%%%%%%%%%%% strain %%%%%%%%%%%%%%%%%%%%
|
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| 378 | function [VarName,ValCell,Role,units]=strain(DataIn)
|
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| 379 | VarName={};
|
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| 380 | ValCell={};
|
---|
| 381 | Role={};
|
---|
| 382 | units={};
|
---|
| 383 | if isfield(DataIn,'DjUi')
|
---|
[124] | 384 | VarName{1}='strain';
|
---|
| 385 | ValCell{1}=DataIn.DjUi(:,1,2)+DataIn.DjUi(:,2,1);%DVDX+DUDY
|
---|
| 386 | siz=size(ValCell{1});
|
---|
| 387 | ValCell{1}=reshape(ValCell{1},siz(1),1);
|
---|
[156] | 388 | Role{1}='scalar';
|
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[124] | 389 | if isfield(DataIn,'TimeUnit')
|
---|
[8] | 390 | units={[DataIn.TimeUnit '-1']};
|
---|
[124] | 391 | else
|
---|
[8] | 392 | units={[]};
|
---|
[124] | 393 | end
|
---|
| 394 | end
|
---|
[8] | 395 |
|
---|
| 396 | %%%%%%%%%%%%% u %%%%%%%%%%%%%%%%%%%%
|
---|
| 397 | function [VarName,ValCell,Role,units]=u(DataIn)
|
---|
| 398 | VarName={};
|
---|
| 399 | ValCell={};
|
---|
| 400 | Role={};
|
---|
| 401 | units={};
|
---|
| 402 | if isfield(DataIn,'U')
|
---|
| 403 | VarName{1}='U';
|
---|
| 404 | ValCell{1}=DataIn.U;
|
---|
| 405 | Role{1}='scalar';
|
---|
| 406 | if isfield(DataIn,'CoordUnit') && isfield(DataIn,'TimeUnit')
|
---|
| 407 | units={[DataIn.CoordUnit '/' DataIn.TimeUnit]};
|
---|
| 408 | else
|
---|
| 409 | units={'pixel'};
|
---|
| 410 | end
|
---|
| 411 | end
|
---|
| 412 |
|
---|
| 413 | %%%%%%%%%%%%% v %%%%%%%%%%%%%%%%%%%%
|
---|
| 414 | function [VarName,ValCell,Role,units]=v(DataIn)
|
---|
| 415 | VarName={};
|
---|
| 416 | ValCell={};
|
---|
| 417 | Role={};
|
---|
| 418 | units={};
|
---|
| 419 | if isfield(DataIn,'V')
|
---|
| 420 | VarName{1}='V';
|
---|
| 421 | ValCell{1}=DataIn.V;
|
---|
| 422 | Role{1}='scalar';
|
---|
| 423 | if isfield(DataIn,'CoordUnit') && isfield(DataIn,'TimeUnit')
|
---|
| 424 | units={[DataIn.CoordUnit '/' DataIn.TimeUnit]};
|
---|
| 425 | else
|
---|
| 426 | units={'pixel'};
|
---|
| 427 | end
|
---|
| 428 | end
|
---|
| 429 |
|
---|
| 430 | %%%%%%%%%%%%% w %%%%%%%%%%%%%%%%%%%%
|
---|
| 431 | function [VarName,ValCell,Role,units]=w(DataIn)
|
---|
| 432 | VarName={};
|
---|
| 433 | ValCell={};
|
---|
| 434 | Role={};
|
---|
| 435 | units={};
|
---|
| 436 | if isfield(DataIn,'W')
|
---|
| 437 | VarName{1}='W';
|
---|
| 438 | ValCell{1}=DataIn.W;
|
---|
| 439 | Role{1}='scalar';%will remain unchanged by projection
|
---|
| 440 | if isfield(DataIn,'CoordUnit') && isfield(DataIn,'TimeUnit')
|
---|
| 441 | units={[DataIn.CoordUnit '/' DataIn.TimeUnit]};
|
---|
| 442 | else
|
---|
| 443 | units={'pixel'};
|
---|
| 444 | end
|
---|
| 445 | end
|
---|
| 446 |
|
---|
| 447 | %%%%%%%%%%%%% w_normal %%%%%%%%%%%%%%%%%%%%
|
---|
| 448 | function [VarName,ValCell,Role,units]=w_normal(DataIn)
|
---|
| 449 | VarName={};
|
---|
| 450 | ValCell={};
|
---|
| 451 | Role={};
|
---|
| 452 | units={};
|
---|
| 453 | if isfield(DataIn,'W')
|
---|
| 454 | VarName{1}='W';
|
---|
| 455 | ValCell{1}=DataIn.W;
|
---|
[124] | 456 | Role{1}='vector_z';%will behave like a vector component by projection
|
---|
[8] | 457 | if isfield(DataIn,'CoordUnit') && isfield(DataIn,'TimeUnit')
|
---|
| 458 | units={[DataIn.CoordUnit '/' DataIn.TimeUnit]};
|
---|
| 459 | else
|
---|
| 460 | units={'pixel'};
|
---|
| 461 | end
|
---|
| 462 | end
|
---|
| 463 |
|
---|
| 464 | %%%%%%%%%%%%% error %%%%%%%%%%%%%%%%%%%%
|
---|
| 465 | function [VarName,ValCell,Role,units]=error(DataIn)
|
---|
| 466 | VarName={};
|
---|
| 467 | ValCell={};
|
---|
| 468 | Role={};
|
---|
| 469 | units={};
|
---|
| 470 | if isfield(DataIn,'E')
|
---|
| 471 | VarName{1}='E';
|
---|
| 472 | ValCell{1}=DataIn.E;
|
---|
| 473 | Role{1}='ancillary'; %TODO CHECK units in actual fields
|
---|
| 474 | if isfield(DataIn,'CoordUnit') && isfield(DataIn,'TimeUnit')
|
---|
| 475 | units={[DataIn.CoordUnit '/' DataIn.TimeUnit]};
|
---|
| 476 | else
|
---|
| 477 | units={'pixel'};
|
---|
| 478 | end
|
---|
| 479 | end
|
---|
| 480 |
|
---|