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source: trunk/src/proj_field.m @ 100

Last change on this file since 100 was 77, checked in by sommeria, 14 years ago
introduction of volume projection on a regular grid (mode 'interp') using griddata3. It works but very slow. minor bug corrections todo: problem with 3D projection when the same field is read twice (e;g. w used for vector color)
File size: 96.3 KB

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1	%'proj_field': projects the field on a projection object
2	%--------------------------------------------------------------------------
3	% function [ProjData,errormsg]=proj_field(FieldData,ObjectData,IndexObj)
4	%
5	% OUTPUT:
6	% ProjData structure containing the fields of the input field FieldData,
7	% transmitted or projected on the object, plus the additional fields
8	% .UMax, .UMin, .VMax, .VMin: min and max of velocity components in a domain
9	% .UMean,VMean: mean of the velocity components in a domain
10	% .AMin, AMax: min and max of a scalar
11	% .AMean: mean of a scalar in a domain
12	% .NbPix;
13	% .DimName= names of the matrix dimensions (matlab cell)
14	% .DimValue= values of the matricx dimensions (matlab vector, same length as .DimName);
15	% .VarName= names of the variables [ProjData.VarName {'A','AMean','AMin','AMax'}];
16	% .VarDimNameIndex= dimensions of the variables, indicated by indices in the list .DimName;
17	%
18	%INPUT
19	% ObjectData: structure characterizing the projection object
20	% .Style : style of projection object
21	% .ProjMode=type of projection ;
22	% .CoordType: 'px' or 'phys' type of coordinates defining the object position
23	% .Phi angle of rotation (=0 by default)
24	% .ProjAngle=angle of projection;
25	% .DX,.DY,.DZ=increments along each coordinate
26	% .Coord(nbpoints,3): set of coordinates defining the object position;
27
28	%FieldData: data of the field to be projected on the projection object, with optional fields
29	% .Txt: error message, transmitted to the projection
30	% .CoordType: 'px' or 'phys' type of coordinates of the field, must be the same as for the projection object, transmitted
31	% .Mesh: typical distance between data points (used for mouse action or display), transmitted
32	% .CoordUnit, .TimeUnit, .dt: transmitted
33	% standardised description of fields, nc-formated Matlab structure with fields:
34	% .ListGlobalAttribute: cell listing the names of the global attributes
35	% .Att_1,Att_2... : values of the global attributes
36	% .ListDimName: cell listing the names of the array dimensions
37	% .DimValue: array dimension values (Matlab vector with the same length as .ListDimName
38	% .ListVarName: cell listing the names of the variables
39	% .VarDimIndex: cell containing the set of dimension indices (in list .ListDimName) for each variable of .ListVarName
40	% .VarAttribute: cell of structures s containing names and values of variable attributes (s.name=value) for each variable of .ListVarName
41	% .Var1, .Var2....: variables (Matlab arrays) with names listed in .ListVarName
42	% The variables are grouped in 'fields', made of a set of variables with common dimensions (using the function find_field_indices)
43	% The variable attribute 'Role' is used to define the role for plotting:
44	% Role = 'scalar': (default) represents a scalar field
45	% = 'coord': represents a set of unstructured coordinates, whose
46	% space dimension is given by the last array dimension (called 'nb_dim').
47	% = 'coord_x', 'coord_y', 'coord_z': represents a separate set of
48	% unstructured coordinate x, y or z
49	% = 'vector': represents a vector field whose number of components
50	% is given by the last dimension (called 'nb_dim')
51	% = 'vector_x', 'vector_y', 'vector_z' :represents the x, y or z component of a vector
52	% = 'warnflag' : provides a warning flag about the quality of data in a 'Field', default=0, no warning
53	% = 'errorflag': provides an error flag marking false data,
54	% default=0, no error. Different non zero values can represent different criteria of elimination.
55	%
56	% Default role of variables (by name)
57	% vector field:
58	% .X,.Y: position of the velocity vectors, projected on the object
59	% .U, .V, .W: velocity components, projected on the object
60	% .C, .CName: scalar associated to the vector
61	% .F : equivalent to 'warnflag'
62	% .FF: equivalent to 'errorflag'
63	% scalar field or image:
64	% .AName: name of a scalar (to be calculated from velocity fields after projection), transmitted
65	% .A: scalar, projected on the object
66	% .AX, .AY: positions for the scalar
67	% case of a structured grid: A is a dim 2 matrix and .AX=[first last] (length 2 vector) represents the first and last abscissa of the grid
68	% case of an unstructured scalar: A is a vector, AX and AY the corresponding coordinates
69	%
70	%AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
71	% Copyright Joel Sommeria, 2008, LEGI / CNRS-UJF-INPG, sommeria@coriolis-legi.org.
72	%AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
73	% This file is part of the toolbox UVMAT.
74	%
75	% UVMAT is free software; you can redistribute it and/or modify
76	% it under the terms of the GNU General Public License as published by
77	% the Free Software Foundation; either version 2 of the License, or
78	% (at your option) any later version.
79	%
80	% UVMAT is distributed in the hope that it will be useful,
81	% but WITHOUT ANY WARRANTY; without even the implied warranty of
82	% MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
83	% GNU General Public License (file UVMAT/COPYING.txt) for more details.
84	%AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
85
86	function [ProjData,errormsg]=proj_field(FieldData,ObjectData,IndexObj)
87
88	if isfield(ObjectData,'ProjMode') && (isequal(ObjectData.ProjMode,'none')\|\|isequal(ObjectData.ProjMode,'mask_inside')\|\|isequal(ObjectData.ProjMode,'mask_outside'))
89	ProjData=[];
90	return
91	end
92	%introduce default field properties (reading old standards)
93	if ~isfield(ObjectData,'Style')\|\|~isfield(ObjectData,'Coord')\|\|~isfield(ObjectData,'ProjMode')
94	ProjData=FieldData;
95	return
96	end
97
98	% OBSOLETE
99	if isfield(ObjectData,'XMax') && ~isempty(ObjectData.XMax)
100	ObjectData.RangeX(1)=ObjectData.XMax;
101	end
102	if isfield(ObjectData,'XMin') && ~isempty(ObjectData.XMin)
103	ObjectData.RangeX(2)=ObjectData.XMin;
104	end
105	if isfield(ObjectData,'YMax') && ~isempty(ObjectData.YMax)
106	ObjectData.RangeY(1)=ObjectData.YMax;
107	end
108	if isfield(ObjectData,'YMin') && ~isempty(ObjectData.YMin)
109	ObjectData.RangeY(2)=ObjectData.YMin;
110	end
111	if isfield(ObjectData,'ZMax') && ~isempty(ObjectData.ZMax)
112	ObjectData.RangeZ(1)=ObjectData.ZMax;
113	end
114	if isfield(ObjectData,'ZMin') && ~isempty(ObjectData.ZMin)
115	ObjectData.RangeZ(2)=ObjectData.ZMin;
116	end
117	%%%%%%%%%%
118
119	% FieldData=document_field(FieldData);%transform FieldData to the standard format
120	% if ~isfield(FieldData,'VarAttribute')
121	% FieldData.VarAttribute={};
122	% end
123	switch ObjectData.Style
124	case 'points'
125	[ProjData,errormsg]=proj_points(FieldData,ObjectData);
126	case {'line','polyline'}
127	[ProjData,errormsg] = proj_line(FieldData,ObjectData);
128	case {'polygon','rectangle','ellipse'}
129	if isequal(ObjectData.ProjMode,'inside')\|\|isequal(ObjectData.ProjMode,'outside')
130	[ProjData,errormsg] = proj_patch(FieldData,ObjectData);
131	else
132	[ProjData,errormsg] = proj_line(FieldData,ObjectData);
133	end
134	%A FAIRE : GERER MASK
135	case 'plane'
136	% if isfield(FieldData,'NbDim') & isequal(FieldData.NbDim,3)
137	% ProjData= proj_plane3D(FieldData,ObjectData);%
138	% else
139	[ProjData,errormsg] = proj_plane(FieldData,ObjectData);
140	% end
141	case 'volume'
142	[ProjData,errormsg] = proj_volume(FieldData,ObjectData);
143	end
144	if exist('IndexObj','var')
145	ProjData.IndexObj=IndexObj;%transfer object index
146	end
147
148	%-----------------------------------------------------------------
149	%project on a set of points
150	function [ProjData,errormsg]=proj_points(FieldData,ObjectData)%%
151	%-------------------------------------------------------------------
152
153	siz=size(ObjectData.Coord);
154	width=0;
155	if isfield(ObjectData,'Range')
156	width=ObjectData.Range(1,2);
157	end
158	if isfield(ObjectData,'RangeX')&&~isempty(ObjectData.RangeX)
159	width=max(ObjectData.RangeX);
160	end
161	if isfield(ObjectData,'RangeY')&&~isempty(ObjectData.RangeY)
162	width=max(width,max(ObjectData.RangeY));
163	end
164	if isfield(ObjectData,'RangeZ')&&~isempty(ObjectData.RangeZ)
165	width=max(width,max(ObjectData.RangeZ));
166	end
167	if isequal(ObjectData.ProjMode,'projection')
168	if width==0
169	errormsg='projection range around points needed';
170	return
171	end
172	elseif ~isequal(ObjectData.ProjMode,'interp')
173	errormsg=(['ProjMode option ' ObjectData.ProjMode ' not available in proj_field']);
174	return
175	end
176	ProjData=proj_heading(FieldData,ObjectData);
177	ProjData.NbDim=0;
178	%ProjData.ListDimName= {'nb_points'};
179	%ProjData.DimValue=siz(1); %nbre of projection points
180
181
182	% idimvar=0;
183	[CellVarIndex,NbDim,VarTypeCell,errormsg]=find_field_indices(FieldData);
184	if ~isempty(errormsg)
185	errormsg=['error in proj_field/proj_points:' errormsg];
186	return
187	end
188	%LOOP ON GROUPS OF VARIABLES SHARING THE SAME DIMENSIONS
189	% CellVarIndex=cells of variable index arrays
190	% ivar_new=0; % index of the current variable in the projected field
191	% icoord=0;
192	for icell=1:length(CellVarIndex)
193	if NbDim(icell)==1
194	continue
195	end
196	VarIndex=CellVarIndex{icell};% indices of the selected variables in the list FieldData.ListVarName
197	VarType=VarTypeCell{icell};
198	ivar_X=VarType.coord_x;
199	ivar_Y=VarType.coord_y;
200	ivar_Z=VarType.coord_z;
201	% ivar_U=VarType.vector_x;
202	% ivar_V=VarType.vector_y;
203	% ivar_W=VarType.vector_z;
204	% ivar_C=VarType.scalar ;
205	ivar_Anc=VarType.ancillary;
206	% test_anc=zeros(size(VarIndex));
207	test_anc(ivar_Anc)=ones(size(ivar_Anc));
208	ivar_F=VarType.warnflag;
209	ivar_FF=VarType.errorflag;
210	VarIndex([ivar_X ivar_Y ivar_Z ivar_Anc ivar_F ivar_FF])=[];% not projected variables removed frlom list
211	if isempty(ivar_X)
212	test_grid=1;%test for input data on regular grid (e.g. image)coordinates
213
214	else
215	if length(ivar_X)>1 \| length(ivar_Y)>1 \| length(ivar_Z)>1
216	errormsg='multiple coordinate input in proj_field.m';
217	return
218	end
219	if length(ivar_Y)~=1
220	errormsg='y coordinate not defined in proj_field.m';
221	return
222	end
223	test_grid=0;
224	end
225	ProjData.ListVarName={'Y','X','NbVal'};
226	ProjData.VarDimName={'nb_points','nb_points','nb_points'};
227	%ProjData.VarDimIndex={[1],[1],[1]};
228	ProjData.VarAttribute{1}.Role='ancillary';
229	ProjData.VarAttribute{2}.Role='ancillary';
230	ProjData.VarAttribute{3}.Role='ancillary';
231	for ivar=VarIndex
232	VarName=FieldData.ListVarName{ivar};
233	ProjData.ListVarName=[ProjData.ListVarName {VarName}];
234	%ProjData.VarDimIndex=[ProjData.VarDimIndex {[1]}];
235	ProjData.VarDimName=[ProjData.VarDimName {'nb_points'}];
236	end
237	if ~test_grid
238	eval(['coord_x=FieldData.' FieldData.ListVarName{ivar_X} ';'])
239	eval(['coord_y=FieldData.' FieldData.ListVarName{ivar_Y} ';'])
240	test3D=0;% TEST 3D CASE : NOT COMPLETED , 3D CASE : NOT COMPLETED
241	if length(ivar_Z)==1
242	eval(['coord_z=FieldData.' FieldData.ListVarName{ivar_Z} ';'])
243	test3D=1;
244	end
245	if length(ivar_F)>1 \| length(ivar_FF)>1
246	msgbox_uvmat('ERROR','multiple flag input in proj_field.m')
247	return
248	end
249	for ipoint=1:siz(1)
250	Xpoint=ObjectData.Coord(ipoint,:);
251	distX=coord_x-Xpoint(1);
252	distY=coord_y-Xpoint(2);
253	dist=distX.distX+distY.distY;
254	indsel=find(dist<width*width);
255	ProjData.X(ipoint,1)=Xpoint(1);
256	ProjData.Y(ipoint,1)=Xpoint(2);
257	if isequal(length(ivar_FF),1)
258	FFName=FieldData.ListVarName{ivar_FF};
259	eval(['FF=FieldData.' FFName '(indsel);'])
260	ind_indsel=find(~FF);
261	indsel=indsel(ind_indsel);
262	end
263	ProjData.NbVal(ipoint,1)=length(indsel);
264	for ivar=VarIndex
265	VarName=FieldData.ListVarName{ivar};
266	if isempty(indsel)
267	eval(['ProjData.' VarName '(ipoint,1)=NaN;'])
268	else
269	eval(['Var=FieldData.' VarName '(indsel);'])
270	eval(['ProjData.' VarName '(ipoint,1)=mean(Var);'])
271	if isequal(ObjectData.ProjMode,'interp')
272	eval(['ProjData.' VarName '(ipoint,1)=griddata_uvmat(coord_x(indsel),coord_y(indsel),Var,Xpoint(1),Xpoint(2)))';])
273	end
274	end
275	end
276	end
277	else
278	%DimIndices=FieldData.VarDimIndex{VarIndex(1)};%indices of the dimensions of the first variable (common to all variables in the cell)
279	%case of structured coordinates
280	if numel(VarType.coord)>=2 & VarType.coord(1:2) > 0;
281	AYName=FieldData.ListVarName{VarType.coord(1)};
282	AXName=FieldData.ListVarName{VarType.coord(2)};
283	eval(['AX=FieldData.' AXName ';']);% set of x positions
284	eval(['AY=FieldData.' AYName ';']);% set of y positions
285	AName=FieldData.ListVarName{VarIndex(1)};
286	eval(['A=FieldData.' AName ';']);% scalar
287	npxy=size(A);
288
289	% % nbcolor=1; %default
290	% for idim=1:length(ListDimName)
291	% DimName=ListDimName{idim};
292	% if isequal(DimName,'rgb')\|isequal(DimName,'nb_coord')\|isequal(DimName,'nb_coord_i')
293	% nbcolor=npxy(idim);
294	% DimIndices(idim)=[];
295	% npxy(idim)=[];
296	% end
297	% if isequal(DimName,'nb_coord_j')% NOTE: CASE OF TENSOR NOT TREATED
298	% DimIndices(idim)=[];
299	% npxy(idim)=[];
300	% end
301	% end
302	ind_1=find(npxy==1);
303	%DimIndices(ind_1)=[]; %suppress singleton dimensions
304	% indxy=find(DimVarIndex(DimIndices));%select dimension variables (DimIndices non zero)
305	%nb_dim=length(DimIndices)%number of space dimensions
306	nb_dim=numel(VarType.coord);
307	Coord_z=[];
308	Coord_y=[];
309	Coord_x=[];
310	for idim=1:nb_dim %loop on space dimensions
311	test_interp(idim)=0;%test for coordiate interpolation (non regular grid), =0 by default
312	test_coord(idim)=0;%test for defined coordinates, =0 by default
313	%ivar=DimVarIndex(DimIndices(idim));% index of the variable corresponding to the current dimension
314	ivar=VarType.coord(idim);
315	% if ~isequal(ivar,0)% a variable corresponds to the current dimension
316	eval(['Coord{idim}=FieldData.' FieldData.ListVarName{ivar} ';']) ;% position for the first index
317	if numel(Coord{idim})==2
318	DCoord_min(idim)= (Coord{idim}(2)-Coord{idim}(1))/(npxy(idim)-1);
319	else
320	DCoord=diff(Coord{idim});
321	DCoord_min(idim)=min(DCoord);
322	DCoord_max=max(DCoord);
323	test_direct(idim)=DCoord_max>0;% =1 for increasing values, 0 otherwise
324	test_direct_min=DCoord_min(idim)>0;% =1 for increasing values, 0 otherwise
325	if ~isequal(test_direct(idim),test_direct_min)
326	errormsg=['non monotonic dimension variable # ' num2str(idim) ' in proj_field.m'];
327	return
328	end
329	test_interp(idim)=(DCoord_max-DCoord_min(idim))> 0.0001*abs(DCoord_max);% test grid regularity
330	test_coord(idim)=1;
331	end
332	% else % no variable associated with the first dimension, look fo variable attributes Coord_1, _2 or _3
333	% Coord_i_str=['Coord_' num2str(idim)];
334	% DCoord_min(idim)=1;%default
335	% Coord{idim}=[0.5 npxy(idim)];
336	% test_direct(idim)=1;
337	% end
338	end
339	DX=DCoord_min(2);
340	DY=DCoord_min(1);
341	for ipoint=1:siz(1)
342	xwidth=width/(abs(DX));
343	ywidth=width/(abs(DY));
344	i_min=round((ObjectData.Coord(ipoint,1)-Coord{2}(1))/DX+0.5-xwidth); %minimum index of the selected region
345	i_min=max(1,i_min);%restrict to field limit
346	i_plus=round((ObjectData.Coord(ipoint,1)-Coord{2}(1))/DX+0.5+xwidth);
347	i_plus=min(npxy(2),i_plus); %restrict to field limit
348	j_min=round((ObjectData.Coord(ipoint,2)-Coord{1}(1))/DY-ywidth+0.5);
349	j_min=max(1,j_min);
350	j_plus=round((ObjectData.Coord(ipoint,2)-Coord{1}(1))/DY+ywidth+0.5);
351	j_plus=min(npxy(1),j_plus);
352	ProjData.X(ipoint,1)=ObjectData.Coord(ipoint,1);
353	ProjData.Y(ipoint,1)=ObjectData.Coord(ipoint,2);
354	i_int=[i_min:i_plus];
355	j_int=[j_min:j_plus];
356	ProjData.NbVal(ipoint,1)=length(j_int)*length(i_int);
357	if isempty(i_int) \| isempty(j_int)
358	for ivar=VarIndex
359	eval(['ProjData.' FieldData.ListVarName{ivar} '(ipoint,:)=NaN;']);
360	end
361	errormsg=['no data points in the selected projection range ' num2str(width) ];
362	else
363	%TODO: introduce circle in the selected subregion
364	%[I,J]=meshgrid([1:j_int],[1:i_int]);
365	for ivar=VarIndex
366	eval(['Avalue=FieldData.' FieldData.ListVarName{ivar} '(j_int,i_int,:);']);
367	eval(['ProjData.' FieldData.ListVarName{ivar} '(ipoint,:)=mean(mean(Avalue));']);
368	end
369	end
370	end
371	end
372	end
373	end
374
375	%-----------------------------------------------------------------
376	%project in a patch
377	function [ProjData,errormsg]=proj_patch(FieldData,ObjectData)%%
378	%-------------------------------------------------------------------
379	ProjData=proj_heading(FieldData,ObjectData);
380
381	objectfield=fieldnames(ObjectData);
382	widthx=0;
383	widthy=0;
384	if isfield(ObjectData,'RangeX')&~isempty(ObjectData.RangeX)
385	widthx=max(ObjectData.RangeX);
386	end
387	if isfield(ObjectData,'RangeY')&~isempty(ObjectData.RangeY)
388	widthy=max(ObjectData.RangeY);
389	end
390
391	%A REVOIR, GENERALISER: UTILISER proj_line
392	ProjData.NbDim=1;
393	ProjData.ListDimName={};%name of dimension
394	ProjData.DimValue=[];%values of dimension (nbre of vectors)
395	ProjData.ListVarName={};
396	%ProjData.VarDimIndex={};
397	ProjData.VarDimName={};
398	if isfield (FieldData,'ListVarAttribute')
399	ProjData.ListVarAttribute=FieldData.ListVarAttribute;%list of variable attribute names
400	for iattr=1:length(ProjData.ListVarAttribute)%initialization of variable attribute values
401	AttrName=ProjData.ListVarAttribute{iattr};
402	eval(['ProjData.' AttrName '={};'])
403	end;
404	end
405
406	%group the variables (fields of 'FieldData') in cells of variables with the same dimensions
407	testfalse=0;
408	ListIndex={};
409	% DimVarIndex=0;%initilise list of indices for dimension variables
410	idimvar=0;
411	[CellVarIndex,NbDim,VarTypeCell,errormsg]=find_field_indices(FieldData);
412	if ~isempty(errormsg)
413	errormsg=['error in proj_field/proj_patch:' errormsg];
414	return
415	end
416
417	%LOOP ON GROUPS OF VARIABLES SHARING THE SAME DIMENSIONS
418	dimcounter=0;
419	for icell=1:length(CellVarIndex)
420	testX=0;
421	testY=0;
422	test_Amat=0;
423	testfalse=0;
424	VarIndex=CellVarIndex{icell};% indices of the selected variables in the list FieldData.ListVarName
425	VarType=VarTypeCell{icell};
426	% DimIndices=FieldData.VarDimIndex{VarIndex(1)};%indices of the dimensions of the first variable (common to all variables in the cell)
427	if NbDim(icell)~=2% proj_patch acts only on fields of space dimension 2
428	continue
429	end
430	testX=~isempty(VarType.coord_x) && ~isempty(VarType.coord_y);
431	testfalse=~isempty(VarType.errorflag);
432	testproj(VarIndex)=zeros(size(VarIndex));%default
433	testproj(VarType.scalar)=1;
434	testproj(VarType.vector_x)=1;
435	testproj(VarType.vector_y)=1;
436	testproj(VarType.vector_z)=1;
437	testproj(VarType.image)=1;
438	testproj(VarType.color)=1;
439	VarIndex=VarIndex(find(testproj(VarIndex)));%select only the projected variables
440	if testX %case of unstructured coordinates
441	eval(['nbpoint=numel(FieldData.' FieldData.ListVarName{VarIndex(1)} ');'])
442	for ivar=[VarIndex VarType.coord_x VarType.coord_y VarType.errorflag]
443	VarName=FieldData.ListVarName{ivar};
444	eval(['FieldData.' VarName '=reshape(FieldData.' VarName ',nbpoint,1);'])
445	end
446	XName=FieldData.ListVarName{VarType.coord_x};
447	YName=FieldData.ListVarName{VarType.coord_y};
448	eval(['coord_x=FieldData.' XName ';'])
449	eval(['coord_y=FieldData.' YName ';'])
450	end
451	if testfalse
452	FFName=FieldData.ListVarName{VarType.errorflag};
453	eval(['errorflag=FieldData.' FFName ';'])
454	end
455	% image or 2D matrix
456	if numel(VarType.coord)>=2 & VarType.coord(1:2) > 0;
457	test_Amat=1;%image or 2D matrix
458	AYName=FieldData.ListVarName{VarType.coord(1)};
459	AXName=FieldData.ListVarName{VarType.coord(2)};
460	eval(['AX=FieldData.' AXName ';'])% x coordinate
461	eval(['AY=FieldData.' AYName ';'])% y coordinate
462	VarName=FieldData.ListVarName{VarIndex(1)};
463	eval(['DimValue=size(FieldData.' VarName ');'])
464	testcolor=find(numel(DimValue)==3);
465	% errormsg='multicomponent field not projected';
466
467	for idim=1:length(DimValue)
468	Coord_i_str=['Coord_' num2str(idim)];
469	DCoord_min(idim)=1;%default
470	Coord{idim}=[0.5 DimValue(idim)];
471	test_direct(idim)=1;
472	end
473	AX=linspace(Coord{2}(1),Coord{2}(2),DimValue(2));
474	AY=linspace(Coord{1}(1),Coord{1}(2),DimValue(1)); %TODO : 3D case
475	if length(DimValue)==3
476	testcolor=1;
477	npxy(3)=3;
478	else
479	testcolor=0;
480	npxy(3)=1;
481	end
482	[Xi,Yi]=meshgrid(AX,AY);
483	npxy(1)=length(AY);
484	npxy(2)=length(AX);
485	Xi=reshape(Xi,npxy(1)*npxy(2),1);
486	Yi=reshape(Yi,npxy(1)*npxy(2),1);
487	for ivar=1:length(VarIndex)
488	VarName=FieldData.ListVarName{VarIndex(ivar)};
489	eval(['FieldData.' VarName '=reshape(FieldData.' VarName ',npxy(1)*npxy(2),npxy(3));']); % keep only non false vectors
490	end
491	end
492	%select the indices in the range of action
493	testin=[];%default
494	if isequal(ObjectData.Style,'rectangle')
495	% if ~isfield(ObjectData,'RangeX')\|~isfield(ObjectData,'RangeY')
496	% errormsg='rectangle half sides RangeX and RangeY needed'
497	% return
498	% end
499	if testX
500	distX=abs(coord_x-ObjectData.Coord(1,1));
501	distY=abs(coord_y-ObjectData.Coord(1,2));
502	testin=distX<widthx & distY<widthy;
503	elseif test_Amat
504	distX=abs(Xi-ObjectData.Coord(1,1));
505	distY=abs(Yi-ObjectData.Coord(1,2));
506	testin=distX<widthx & distY<widthy;
507	end
508	elseif isequal(ObjectData.Style,'polygon')
509	if testX
510	testin=inpolygon(coord_x,coord_y,ObjectData.Coord(:,1),ObjectData.Coord(:,2));
511	elseif test_Amat
512	testin=inpolygon(Xi,Yi,ObjectData.Coord(:,1),ObjectData.Coord(:,2));
513	else%calculate the scalar
514	testin=[]; %A REVOIR
515	end
516	elseif isequal(ObjectData.Style,'ellipse')
517	X2Max=widthx*widthx;
518	Y2Max=(widthy)*(widthy);
519	if testX
520	distX=(coord_x-ObjectData.Coord(1,1));
521	distY=(coord_y-ObjectData.Coord(1,2));
522	testin=(distX.distX/X2Max+distY.distY/Y2Max)<1;
523	elseif test_Amat %case of usual 2x2 matrix
524	distX=(Xi-ObjectData.Coord(1,1));
525	distY=(Yi-ObjectData.Coord(1,2));
526	testin=(distX.distX/X2Max+distY.distY/Y2Max)<1;
527	end
528	end
529	%selected indices
530	if isequal(ObjectData.ProjMode,'outside')
531	testin=~testin;
532	end
533	if testfalse
534	testin=testin & (errorflag==0); % keep only non false vectors
535	end
536	indsel=find(testin);
537	for ivar=VarIndex
538	if testproj(ivar)
539	VarName=FieldData.ListVarName{ivar};
540	eval(['ProjData.' VarName 'Mean=mean(mean(double(FieldData.' VarName '(indsel,:))));']); % keep only non false vectors
541	eval(['[ProjData.' VarName 'Histo,ProjData.' VarName ']=hist(double(FieldData.' VarName '(indsel,:)),100);']); % keep only non false vectors
542	ProjData.ListVarName=[ProjData.ListVarName {VarName} {[VarName 'Histo']} {[VarName 'Mean']}];
543	if test_Amat && testcolor
544	ProjData.VarDimName=[ProjData.VarDimName {VarName} {{VarName,'rgb'}} {'rgb'}];%{{'nb_point','rgb'}};
545	else
546	ProjData.VarDimName=[ProjData.VarDimName {VarName} {VarName} {'nbpoint'}];
547	end
548	end
549	end
550	% if test_Amat & testcolor
551	% %ProjData.ListDimName=[ProjData.ListDimName {'rgb'}];
552	% % ProjData.DimValue=[ProjData.DimValue 3];
553	% % ProjData.VarDimIndex={[1 2]};
554	% ProjData.VarDimName=[ProjData.VarDimName {VarName} {VarName,'rgb'}];%{{'nb_point','rgb'}};
555	% ProjData.VarDimName
556	% end
557	end
558
559
560
561	%-----------------------------------------------------------------
562	%project on a line
563	% AJOUTER flux,circul,error
564	function [ProjData,errormsg] = proj_line(FieldData, ObjectData)
565	%-----------------------------------------------------------------
566	ProjData=proj_heading(FieldData,ObjectData);%transfer global attributes
567	ProjData.NbDim=1;
568
569	%initialisation of the input parameters and defaultoutput
570	ProjMode='projection';%direct projection on the line by default
571	if isfield(ObjectData,'ProjMode'),ProjMode=ObjectData.ProjMode; end;
572	ProjAngle=90; %90 degrees projection by default
573	if isfield(FieldData,'ProjAngle'),ProjAngle=ObjectData.ProjAngle; end;
574	width=0;%default width of the projection band
575	if isfield(ObjectData,'Range')&size(ObjectData.Range,2)>=2
576	width=abs(ObjectData.Range(1,2));
577	end
578	if isfield(ObjectData,'RangeY')
579	width=max(ObjectData.RangeY);
580	end
581
582	% default output
583	errormsg=[];%default
584	Xline=[];
585	flux=0;
586	circul=0;
587	liny=ObjectData.Coord(:,2);
588	siz_line=size(ObjectData.Coord);
589	if siz_line(1)<2
590	return% line needs at least 2 points to be defined
591	end
592	testfalse=0;
593	ListIndex={};
594
595	%angles of the polyline and boundaries of action
596	dlinx=diff(ObjectData.Coord(:,1));
597	dliny=diff(ObjectData.Coord(:,2));
598	theta=angle(dlinx+i*dliny);%angle of each segment
599	theta(siz_line(1))=theta(siz_line(1)-1);
600	% determine a rectangles at +-width from the line (only used for the ProjMode='projection or 'filter')
601	if isequal(ProjMode,'projection') \|\| isequal(ProjMode,'filter')
602	xsup(1)=ObjectData.Coord(1,1)-width*sin(theta(1));
603	xinf(1)=ObjectData.Coord(1,1)+width*sin(theta(1));
604	ysup(1)=ObjectData.Coord(1,2)+width*cos(theta(1));
605	yinf(1)=ObjectData.Coord(1,2)-width*cos(theta(1));
606	for ip=2:siz_line(1)
607	xsup(ip)=ObjectData.Coord(ip,1)-width*sin((theta(ip)+theta(ip-1))/2)/cos((theta(ip-1)-theta(ip))/2);
608	xinf(ip)=ObjectData.Coord(ip,1)+width*sin((theta(ip)+theta(ip-1))/2)/cos((theta(ip-1)-theta(ip))/2);
609	ysup(ip)=ObjectData.Coord(ip,2)+width*cos((theta(ip)+theta(ip-1))/2)/cos((theta(ip-1)-theta(ip))/2);
610	yinf(ip)=ObjectData.Coord(ip,2)-width*cos((theta(ip)+theta(ip-1))/2)/cos((theta(ip-1)-theta(ip))/2);
611	end
612	end
613
614	%group the variables (fields of 'FieldData') in cells of variables with the same dimensions
615	[CellVarIndex,NbDim,VarTypeCell,errormsg]=find_field_indices(FieldData);
616	if ~isempty(errormsg)
617	errormsg=['error in proj_field/proj_line:' errormsg];
618	return
619	end
620
621	% loop on variable cells with the same space dimension
622	ProjData.ListVarName={};
623	ProjData.VarDimName={};
624	for icell=1:length(CellVarIndex)
625	VarIndex=CellVarIndex{icell};% indices of the selected variables in the list FieldData.ListVarName
626	VarType=VarTypeCell{icell}; %types of variables
627	if NbDim(icell)~=2% proj_line acts only on fields of space dimension 2, TODO: check 3D case
628	continue
629	end
630	testX=~isempty(VarType.coord_x) && ~isempty(VarType.coord_y);% test for unstructured coordinates
631	testU=~isempty(VarType.vector_x) && ~isempty(VarType.vector_y);% test for vectors
632	testfalse=~isempty(VarType.errorflag);% test for error flag
633	testproj(VarIndex)=zeros(size(VarIndex));% test =1 for simply projected variables, default =0
634	%=0 for vector components, treated separately
635	testproj(VarType.scalar)=1;
636	testproj(VarType.image)=1;
637	testproj(VarType.color)=1;
638	VarIndex=VarIndex(find(testproj(VarIndex)));%select only the projected variables
639	if testU
640	VarIndex=[VarIndex VarType.vector_x VarType.vector_y];%append u and v at the end of the list of variables
641	end
642	%identify vector components
643	if testU
644	UName=FieldData.ListVarName{VarType.vector_x};
645	VName=FieldData.ListVarName{VarType.vector_y};
646	eval(['vector_x=FieldData.' UName ';'])
647	eval(['vector_y=FieldData.' VName ';'])
648	end
649	%identify error flag
650	if testfalse
651	FFName=FieldData.ListVarName{VarType.errorflag};
652	eval(['errorflag=FieldData.' FFName ';'])
653	end
654	% check needed object properties for unstructured positions (position given by the variables with role coord_x, coord_y
655	if testX
656	if ~isequal(ProjMode,'interp')
657	if width==0
658	errormsg='range of the projection object is missing';
659	return
660	else
661	lambda=2/(width*width); %smoothing factor used for filter: weight exp(-2) at distance width from the line
662	end
663	end
664	if ~isequal(ProjMode,'projection')
665	if isfield(ObjectData,'DX')&~isempty(ObjectData.DX)
666	DX=abs(ObjectData.DX);%mesh of interpolation points along the line
667	else
668	errormsg='DX missing';
669	return
670	end
671	end
672	XName= FieldData.ListVarName{VarType.coord_x};
673	YName= FieldData.ListVarName{VarType.coord_y};
674	eval(['coord_x=FieldData.' XName ';'])
675	eval(['coord_y=FieldData.' YName ';'])
676	end
677	%initiate projection
678	for ivar=1:length(VarIndex)
679	ProjLine{ivar}=[];
680	end
681	XLine=[];
682	linelengthtot=0;
683
684	% circul=0;
685	% flux=0;
686	%%%%%%% % A FAIRE CALCULER MEAN DES QUANTITES %%%%%%
687	%case of unstructured coordinates
688	if testX
689	for ip=1:siz_line(1)-1 %Loop on the segments of the polyline
690	linelength=sqrt(dlinx(ip)dlinx(ip)+dliny(ip)dliny(ip));
691	%select the vector indices in the range of action
692	if testfalse
693	flagsel=(errorflag==0); % keep only non false vectors
694	else
695	flagsel=ones(size(coord_x));
696	end
697	if isequal(ProjMode,'projection') \| isequal(ProjMode,'filter')
698	flagsel=flagsel & ((coord_y -yinf(ip))(xinf(ip+1)-xinf(ip))>(coord_x-xinf(ip))(yinf(ip+1)-yinf(ip))) ...
699	& ((coord_y -ysup(ip))(xsup(ip+1)-xsup(ip))<(coord_x-xsup(ip))(ysup(ip+1)-ysup(ip))) ...
700	& ((coord_y -yinf(ip+1))(xsup(ip+1)-xinf(ip+1))>(coord_x-xinf(ip+1))(ysup(ip+1)-yinf(ip+1))) ...
701	& ((coord_y -yinf(ip))(xsup(ip)-xinf(ip))<(coord_x-xinf(ip))(ysup(ip)-yinf(ip)));
702	end
703	indsel=find(flagsel);%indsel =indices of good vectors
704	X_sel=coord_x(indsel);
705	Y_sel=coord_y(indsel);
706	nbvar=0;
707	for iselect=1:numel(VarIndex)-2*testU
708	VarName=FieldData.ListVarName{VarIndex(iselect)};
709	eval(['ProjVar{iselect}=FieldData.' VarName '(indsel);']);%scalar value
710	end
711	if testU
712	ProjVar{numel(VarIndex)-1}=cos(theta(ip))vector_x(indsel)+sin(theta(ip))vector_y(indsel);% longitudinal component
713	ProjVar{numel(VarIndex)}=-sin(theta(ip))vector_x(indsel)+cos(theta(ip))vector_y(indsel);%transverse component
714	end
715	if isequal(ProjMode,'projection')
716	sintheta=sin(theta(ip));
717	costheta=cos(theta(ip));
718	Xproj=(X_sel-ObjectData.Coord(ip,1))costheta + (Y_sel-ObjectData.Coord(ip,2))sintheta; %projection on the line
719	[Xproj,indsort]=sort(Xproj);
720	for ivar=1:numel(ProjVar)
721	if ~isempty(ProjVar{ivar})
722	ProjVar{ivar}=ProjVar{ivar}(indsort);
723	end
724	end
725	elseif isequal(ProjMode,'interp') %linear interpolation:
726	npoint=floor(linelength/DX)+1;% nbre of points in the profile (interval DX)
727	Xproj=[linelength/(2npoint):linelength/npoint:linelength-linelength/(2npoint)];
728	xreg=cos(theta(ip))*Xproj+ObjectData.Coord(ip,1);
729	yreg=sin(theta(ip))*Xproj+ObjectData.Coord(ip,2);
730	for ivar=1:numel(ProjVar)
731	if ~isempty(ProjVar{ivar})
732	ProjVar{ivar}=griddata_uvmat(X_sel,Y_sel,ProjVar{ivar},xreg,yreg);
733	end
734	end
735	elseif isequal(ProjMode,'filter') %filtering
736	npoint=floor(linelength/DX)+1;% nbre of points in the profile (interval DX)
737	Xproj=[linelength/(2npoint):linelength/npoint:linelength-linelength/(2npoint)];
738	siz=size(X_sel);
739	xregij=cos(theta(ip))Xproj'ones(1,siz(2))+ObjectData.Coord(ip,1);
740	yregij=sin(theta(ip))Xproj'ones(1,siz(2))+ObjectData.Coord(ip,2);
741	xij=ones(npoint,1)*X_sel;
742	yij=ones(npoint,1)*Y_sel;
743	Aij=exp(-lambda((xij-xregij).(xij-xregij)+(yij-yregij).*(yij-yregij)));
744	norm=ones(1,siz(2))*Aij';
745	for ivar=1:numel(ProjVar)
746	if ~isempty(ProjVar{ivar})
747	ProjVar{ivar}=ProjVar{ivar}*Aij'./norm;
748	end
749	end
750	end
751	%prolongate the total record
752	for ivar=1:numel(ProjVar)
753	if ~isempty(ProjVar{ivar})
754	ProjLine{ivar}=[ProjLine{ivar}; ProjVar{ivar}];
755	end
756	end
757	XLine=[XLine ;(Xproj+linelengthtot)];%along line abscissa
758	linelengthtot=linelengthtot+linelength;
759	% circul=circul+(sum(U_sel))*linelength/npoint;
760	% flux=flux+(sum(V_sel))*linelength/npoint;
761	end
762	ProjData.X=XLine';
763	cur_index=1;
764	ProjData.ListVarName=[ProjData.ListVarName {XName}];
765	ProjData.VarDimName=[ProjData.VarDimName {XName}];
766	ProjData.VarAttribute{1}.long_name='abscissa along line';
767	for iselect=1:numel(VarIndex)
768	VarName=FieldData.ListVarName{VarIndex(iselect)};
769	eval(['ProjData.' VarName '=ProjLine{iselect};'])
770	ProjData.ListVarName=[ProjData.ListVarName {VarName}];
771	ProjData.VarDimName=[ProjData.VarDimName {XName}];
772	ProjData.VarAttribute{iselect}=FieldData.VarAttribute{VarIndex(iselect)};
773	if strcmp(ProjMode,'projection')
774	ProjData.VarAttribute{iselect}.Role='discrete';
775	else
776	ProjData.VarAttribute{iselect}.Role='continuous';
777	end
778	end
779
780	%case of structured coordinates
781	elseif numel(VarType.coord)>=2 & VarType.coord(1:2) > 0;
782	if ~isequal(ObjectData.Style,'line')% exclude polyline
783	errormsg=['no projection available on ' ObjectData.Style 'for structured coordinates']; %
784	else
785	test_Amat=1;%image or 2D matrix
786	test_interp2=0;%default
787	% if ~isempty(VarType.coord_y)
788	AYName=FieldData.ListVarName{VarType.coord(1)};
789	AXName=FieldData.ListVarName{VarType.coord(2)};
790	eval(['AX=FieldData.' AXName ';']);% set of x positions
791	eval(['AY=FieldData.' AYName ';']);% set of y positions
792	AName=FieldData.ListVarName{VarIndex(1)};
793	eval(['A=FieldData.' AName ';']);% scalar
794	npxy=size(A);
795	npx=npxy(2);
796	npy=npxy(1);
797	if numel(AX)==2
798	DX=(AX(2)-AX(1))/(npx-1);
799	else
800	DX_vec=diff(AX);
801	DX=max(DX_vec);
802	DX_min=min(DX_vec);
803	if (DX-DX_min)>0.0001*abs(DX)
804	test_interp2=1;
805	DX=DX_min;
806	end
807	end
808	if numel(AY)==2
809	DY=(AY(2)-AY(1))/(npy-1);
810	else
811	DY_vec=diff(AY);
812	DY=max(DY_vec);
813	DY_min=min(DY_vec);
814	if (DY-DY_min)>0.0001*abs(DY)
815	test_interp2=1;
816	DY=DY_min;
817	end
818	end
819	AXI=linspace(AX(1),AX(end), npx);%set of x positions for the interpolated input data
820	AYI=linspace(AY(1),AY(end), npy);%set of x positions for the interpolated input data
821	if isfield(ObjectData,'DX')
822	DXY_line=ObjectData.DX;%mesh on the projection line
823	else
824	DXY_line=sqrt(abs(DX*DY));% mesh on the projection line
825	end
826	dlinx=ObjectData.Coord(2,1)-ObjectData.Coord(1,1);
827	dliny=ObjectData.Coord(2,2)-ObjectData.Coord(1,2);
828	linelength=sqrt(dlinxdlinx+dlinydliny);
829	theta=angle(dlinx+i*dliny);%angle of the line
830	if isfield(FieldData,'RangeX')
831	XMin=min(FieldData.RangeX);%shift of the origin on the line
832	else
833	XMin=0;
834	end
835	eval(['ProjData.' AXName '=linspace(XMin,XMin+linelength,linelength/DXY_line+1);'])%abscissa of the new pixels along the line
836	y=linspace(-width,width,2*width/DXY_line+1);%ordintes of the new pixels (coordinate across the line)
837	eval(['npX=length(ProjData.' AXName ');'])
838	npY=length(y); %TODO: utiliser proj_grid
839	eval(['[X,Y]=meshgrid(ProjData.' AXName ',y);'])%grid in the line coordinates
840	XIMA=ObjectData.Coord(1,1)+(X-XMin)cos(theta)-Ysin(theta);
841	YIMA=ObjectData.Coord(1,2)+(X-XMin)sin(theta)+Ycos(theta);
842	XIMA=(XIMA-AX(1))/DX+1;% index of the original image along x
843	YIMA=(YIMA-AY(1))/DY+1;% index of the original image along y
844	XIMA=reshape(round(XIMA),1,npX*npY);%indices reorganized in 'line'
845	YIMA=reshape(round(YIMA),1,npX*npY);
846	flagin=XIMA>=1 & XIMA<=npx & YIMA >=1 & YIMA<=npy;%flagin=1 inside the original image
847	ind_in=find(flagin);
848	ind_out=find(~flagin);
849	ICOMB=(XIMA-1)*npy+YIMA;
850	ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
851	nbcolor=1; %color images
852	if numel(npxy)==2
853	nbcolor=1;
854	elseif length(npxy)==3
855	nbcolor=npxy(3);
856	else
857	errormsg='multicomponent field not projected';
858	display(errormsg)
859	return
860	end
861	nbvar=length(ProjData.ListVarName);% number of var from previous cells
862	ProjData.ListVarName=[ProjData.ListVarName {AXName}];
863	ProjData.VarDimName=[ProjData.VarDimName {AXName}];
864	for ivar=VarIndex
865	VarName{ivar}=FieldData.ListVarName{ivar};
866	if test_interp2% interpolate on new grid
867	eval(['FieldData.' VarName{ivar} '=interp2(FieldData.' AXName ',FieldData.' AYName ',FieldData.' VarName{ivar} ',AXI,AYI'');']) %TO TEST
868	end
869	eval(['vec_A=reshape(squeeze(FieldData.' VarName{ivar} '),npx*npy,nbcolor);']) %put the original image in colum
870	if nbcolor==1
871	vec_B(ind_in)=vec_A(ICOMB);
872	vec_B(ind_out)=zeros(size(ind_out));
873	A_out=reshape(vec_B,npY,npX);
874	eval(['ProjData.' VarName{ivar} '=((sum(A_out,1)/npY))'';']);
875	elseif nbcolor==3
876	vec_B(ind_in,[1:3])=vec_A(ICOMB,:);
877	vec_B(ind_out,1)=zeros(size(ind_out));
878	vec_B(ind_out,2)=zeros(size(ind_out));
879	vec_B(ind_out,3)=zeros(size(ind_out));
880	A_out=reshape(vec_B,npY,npX,nbcolor);
881	eval(['ProjData.' VarName{ivar} '=squeeze(sum(A_out,1)/npY);']);
882	end
883	ProjData.ListVarName=[ProjData.ListVarName VarName{ivar} ];
884	ProjData.VarDimName=[ProjData.VarDimName {AXName}];%to generalize with the initial name of the x coordinate
885	ProjData.VarAttribute{ivar}.Role='continuous';% for plot with continuous line
886	end
887	if testU
888	eval(['vector_x =ProjData.' VarName{VarType.vector_x} ';'])
889	eval(['vector_y =ProjData.' VarName{VarType.vector_y} ';'])
890	eval(['ProjData.' VarName{VarType.vector_x} '=cos(theta)vector_x+sin(theta)vector_y;'])
891	eval(['ProjData.' VarName{VarType.vector_y} '=-sin(theta)vector_x+cos(theta)vector_y;'])
892	end
893	ProjData.VarAttribute{nbvar+1}.long_name='abscissa along line';
894	if nbcolor==3
895	ProjData.VarDimName{end}={AXName,'rgb'};
896	end
897	end
898	end
899	end
900
901	% %shotarter case for horizontal or vertical line (A FAIRE
902	% % Rangx=[0.5 npx-0.5];%image coordiantes of corners
903	% % Rangy=[npy-0.5 0.5];
904	% % if isfield(Calib,'Pxcmx')&isfield(Calib,'Pxcmy')%old calib
905	% % Rangx=Rangx/Calib.Pxcmx;
906	% % Rangy=Rangy/Calib.Pxcmy;
907	% % else
908	% % [Rangx]=phys_XYZ(Calib,Rangx,[0.5 0.5],[0 0]);%case of translations without rotation and quadratic deformation
909	% % [xx,Rangy]=phys_XYZ(Calib,[0.5 0.5],Rangy,[0 0]);
910	% % end
911	%
912	% % test_scal=0;%default% 3- 'UserData':(get(handles.Tag,'UserData')
913
914
915	%-----------------------------------------------------------------
916	%project on a plane
917	% AJOUTER flux,circul,error
918	function [ProjData,errormsg] = proj_plane(FieldData, ObjectData)
919	%-----------------------------------------------------------------
920
921	%initialisation of the input parameters of the projection plane
922	%-----------------------------------------------------------------
923	ProjMode='projection';%direct projection by default
924	if isfield(ObjectData,'ProjMode'),ProjMode=ObjectData.ProjMode; end;
925
926	%axis origin
927	if isempty(ObjectData.Coord)
928	ObjectData.Coord(1,1)=0;%origin of the plane set to [0 0] by default
929	ObjectData.Coord(1,2)=0;
930	ObjectData.Coord(1,3)=0;
931	end
932
933	%rotation angles
934	Phi=0;%default
935	Theta=0;
936	Psi=0;
937	if isfield(ObjectData,'Phi')&& ~isempty(ObjectData.Phi)
938	Phi=(pi/180)*ObjectData.Phi;%first Euler angle in radian
939	end
940	if isfield(ObjectData,'Theta')&& ~isempty(ObjectData.Theta)
941	Theta=(pi/180)*ObjectData.Theta;%second Euler angle in radian
942	end
943	if isfield(ObjectData,'Psi')&& ~isempty(ObjectData.Psi)
944	Psi=(pi/180)*ObjectData.Psi;%third Euler angle in radian
945	end
946
947	%components of the unity vector normal to the projection plane
948	NormVec_X=-sin(Phi)*sin(Theta);
949	NormVec_Y=cos(Phi)*sin(Theta);
950	NormVec_Z=cos(Theta);
951
952	% test for 3D fields
953	test3D=0;
954	if isfield(FieldData,'nb_dim')
955	test3D=isequal(FieldData.nb_dim,3);
956	end
957	test3C=test3D; %default 3 vel components
958
959	%mesh sizes DX and DY
960	DX=0;
961	DY=0; %default
962	if isfield(ObjectData,'DX')&~isempty(ObjectData.DX)
963	DX=abs(ObjectData.DX);%mesh of interpolation points
964	end
965	if isfield(ObjectData,'DY')&~isempty(ObjectData.DY)
966	DY=abs(ObjectData.DY);%mesh of interpolation points
967	end
968	if ~isequal(ProjMode,'projection') & (DX==0\|DY==0)
969	errormsg='DX or DY missing';
970	display(errormsg)
971	return
972	end
973
974	%extrema along each axis
975	testXMin=0;
976	testXMax=0;
977	testYMin=0;
978	testYMax=0;
979	if isfield(ObjectData,'RangeX')
980	XMin=min(ObjectData.RangeX);
981	XMax=max(ObjectData.RangeX);
982	testXMin=XMax>XMin;
983	testXMax=1;
984	end
985	if isfield(ObjectData,'RangeY')
986	YMin=min(ObjectData.RangeY);
987	YMax=max(ObjectData.RangeY);
988	testYMin=YMax>YMin;
989	testYMax=1;
990	end
991	width=0;%default width of the projection band
992	if isfield(ObjectData,'RangeZ')
993	width=max(ObjectData.RangeZ);
994	end
995
996	% initiate Matlab structure for physical field
997	ProjData=proj_heading(FieldData,ObjectData);
998	ProjData.NbDim=2;
999	ProjData.ListDimName={};%name of dimension
1000	ProjData.DimValue=[];%values of dimension (nbre of vectors)
1001	ProjData.ListVarName={};
1002	ProjData.VarDimName={};
1003
1004	error=0;%default
1005	flux=0;
1006	testfalse=0;
1007	ListIndex={};
1008
1009	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
1010	%group the variables (fields of 'FieldData') in cells of variables with the same dimensions
1011	%-----------------------------------------------------------------
1012	idimvar=0;
1013	[CellVarIndex,NbDim,VarTypeCell,errormsg]=find_field_indices(FieldData);
1014	if ~isempty(errormsg)
1015	errormsg=['error in proj_field/proj_plane:' errormsg];
1016	return
1017	end
1018	%LOOP ON GROUPS OF VARIABLES SHARING THE SAME DIMENSIONS
1019	% CellVarIndex=cells of variable index arrays
1020	ivar_new=0; % index of the current variable in the projected field
1021	icoord=0;
1022	nbcoord=0;%number of added coordinate variables brought by projection
1023	for icell=1:length(CellVarIndex)
1024	if NbDim(icell)<2
1025	continue
1026	end
1027	VarIndex=CellVarIndex{icell};% indices of the selected variables in the list FieldData.ListVarName
1028	VarType=VarTypeCell{icell};
1029	ivar_X=VarType.coord_x;
1030	ivar_Y=VarType.coord_y;
1031	ivar_Z=VarType.coord_z;
1032	ivar_U=VarType.vector_x;
1033	ivar_V=VarType.vector_y;
1034	ivar_W=VarType.vector_z;
1035	ivar_C=VarType.scalar ;
1036	ivar_Anc=VarType.ancillary;
1037	test_anc=zeros(size(VarIndex));
1038	test_anc(ivar_Anc)=ones(size(ivar_Anc));
1039	ivar_F=VarType.warnflag;
1040	ivar_FF=VarType.errorflag;
1041	testX=~isempty(ivar_X) && ~isempty(ivar_Y);
1042	%DimIndices=FieldData.VarDimIndex{VarIndex(1)};%indices of the dimensions of the first variable (common to all variables in the cell)
1043	DimCell=FieldData.VarDimName{VarIndex(1)};
1044	if ischar(DimCell)
1045	DimCell={DimCell};%name of dimensions
1046	end
1047
1048	%case of input fields with unstructured coordinates
1049	if testX
1050	XName=FieldData.ListVarName{ivar_X};
1051	YName=FieldData.ListVarName{ivar_Y};
1052	eval(['coord_x=FieldData.' XName ';'])
1053	eval(['coord_y=FieldData.' YName ';'])
1054	if length(ivar_Z)==1
1055	ZName=FieldData.ListVarName{ivar_Z};
1056	eval(['coord_z=FieldData.' ZName ';'])
1057	end
1058
1059	% translate initial coordinates
1060	coord_x=coord_x-ObjectData.Coord(1,1);
1061	coord_y=coord_y-ObjectData.Coord(1,2);
1062	if ~isempty(ivar_Z)
1063	coord_z=coord_z-ObjectData.Coord(1,3);
1064	end
1065
1066	% selection of the vectors in the projection range (3D case)
1067	if length(ivar_Z)==1 && width > 0
1068	%components of the unitiy vector normal to the projection plane
1069	fieldZ=NormVec_Xcoord_x + NormVec_Ycoord_y+ NormVec_Z*coord_z;% distance to the plane
1070	indcut=find(abs(fieldZ) <= width);
1071	for ivar=VarIndex
1072	VarName=FieldData.ListVarName{ivar};
1073	% eval(['size(FieldData.' VarName ')'])
1074	eval(['FieldData.' VarName '=FieldData.' VarName '(indcut);'])
1075	% end
1076	% A VOIR : CAS DE VAR STRUCTUREE MAIS PAS GRILLE REGULIERE : INTERPOLER SUR GRILLE REGULIERE
1077	end
1078	coord_x=coord_x(indcut);
1079	coord_y=coord_y(indcut);
1080	coord_z=coord_z(indcut);
1081	end
1082
1083	%rotate coordinates if needed
1084	if isequal(Phi,0)
1085	coord_X=coord_x;
1086	coord_Y=coord_y;
1087	if ~isequal(Theta,0)
1088	coord_Y=coord_Y *cos(Theta);
1089	end
1090	else
1091	coord_X=(coord_x cos(Phi) + coord_y sin(Phi));
1092	coord_Y=(-coord_x sin(Phi) + coord_y cos(Phi))*cos(Theta);
1093	end
1094	if ~isempty(ivar_Z)
1095	coord_Y=coord_Y+coord_z *sin(Theta);
1096	end
1097	if ~isequal(Psi,0)
1098	coord_X=(coord_X cos(Psi) - coord_Y sin(Psi));%A VERIFIER
1099	coord_Y=(coord_X sin(Psi) + coord_Y cos(Psi));
1100	end
1101
1102	%restriction to the range of x and y if imposed
1103	testin=ones(size(coord_X)); %default
1104	testbound=0;
1105	if testXMin
1106	testin=testin & (coord_X >= XMin);
1107	testbound=1;
1108	end
1109	if testXMax
1110	testin=testin & (coord_X <= XMax);
1111	testbound=1;
1112	end
1113	if testYMin
1114	testin=testin & (coord_Y >= YMin);
1115	testbound=1;
1116	end
1117	if testYMin
1118	testin=testin & (coord_Y <= YMax);
1119	testbound=1;
1120	end
1121	if testbound
1122	indcut=find(testin);
1123	for ivar=VarIndex
1124	VarName=FieldData.ListVarName{ivar};
1125	eval(['FieldData.' VarName '=FieldData.' VarName '(indcut);'])
1126	end
1127	coord_X=coord_X(indcut);
1128	coord_Y=coord_Y(indcut);
1129	if length(ivar_Z)==1
1130	coord_Z=coord_Z(indcut);
1131	end
1132	end
1133	% different cases of projection
1134	if isequal(ObjectData.ProjMode,'projection')
1135	%the list of dimension
1136	ProjData.ListDimName=[ProjData.ListDimName FieldData.VarDimName(VarIndex(1))];%add the point index to the list of dimensions
1137	ProjData.DimValue=[ProjData.DimValue length(coord_X)];
1138	nbvar=0;
1139	for ivar=VarIndex %transfer variables to the projection plane
1140	VarName=FieldData.ListVarName{ivar};
1141	if ivar==ivar_X %x coordinate
1142	eval(['ProjData.' VarName '=coord_X;'])
1143	elseif ivar==ivar_Y % y coordinate
1144	eval(['ProjData.' VarName '=coord_Y;'])
1145	elseif isempty(ivar_Z) \|\| ivar~=ivar_Z % other variables (except Z coordinate wyhich is not reproduced)
1146	eval(['ProjData.' VarName '=FieldData.' VarName ';'])
1147	end
1148	if isempty(ivar_Z) \|\| ivar~=ivar_Z
1149	ProjData.ListVarName=[ProjData.ListVarName VarName];
1150	ProjData.VarDimName=[ProjData.VarDimName DimCell];
1151	nbvar=nbvar+1;
1152	if isfield(FieldData,'VarAttribute') & length(FieldData.VarAttribute) >=ivar
1153	ProjData.VarAttribute{nbvar}=FieldData.VarAttribute{ivar};
1154	end
1155	end
1156	end
1157	elseif isequal(ObjectData.ProjMode,'interp')\|\|isequal(ObjectData.ProjMode,'filter')%interpolate data on a regular grid
1158	coord_x_proj=[XMin:DX:XMax];
1159	coord_y_proj=[YMin:DY:YMax];
1160	DimCell={'coord_y','coord_x'};
1161	ProjData.ListVarName={'coord_y','coord_x'};
1162	ProjData.VarDimName={'coord_y','coord_x'};
1163	nbcoord=2;
1164	ProjData.coord_y=[YMin YMax];
1165	ProjData.coord_x=[XMin XMax];
1166	if isempty(ivar_X), ivar_X=0; end;
1167	if isempty(ivar_Y), ivar_Y=0; end;
1168	if isempty(ivar_Z), ivar_Z=0; end;
1169	if isempty(ivar_U), ivar_U=0; end;
1170	if isempty(ivar_V), ivar_V=0; end;
1171	if isempty(ivar_W), ivar_W=0; end;
1172	if isempty(ivar_F), ivar_F=0; end;
1173	if isempty(ivar_FF), ivar_FF=0; end;
1174	if ~isequal(ivar_FF,0)
1175	VarName_FF=FieldData.ListVarName{ivar_FF};
1176	eval(['indsel=find(FieldData.' VarName_FF '==0);'])
1177	coord_X=coord_X(indsel);
1178	coord_Y=coord_Y(indsel);
1179	end
1180	FF=zeros(1,length(coord_y_proj)*length(coord_x_proj));
1181	testFF=0;
1182	for ivar=VarIndex
1183	VarName=FieldData.ListVarName{ivar};
1184	if ~( ivar==ivar_X \|\| ivar==ivar_Y \|\| ivar==ivar_Z \|\| ivar==ivar_F \|\| ivar==ivar_FF \|\| test_anc(ivar)==1)
1185	ivar_new=ivar_new+1;
1186	ProjData.ListVarName=[ProjData.ListVarName {VarName}];
1187	ProjData.VarDimName=[ProjData.VarDimName {DimCell}];
1188	if isfield(FieldData,'VarAttribute') && length(FieldData.VarAttribute) >=ivar
1189	ProjData.VarAttribute{ivar_new+nbcoord}=FieldData.VarAttribute{ivar};
1190	end
1191	if ~isequal(ivar_FF,0)
1192	eval(['FieldData.' VarName '=FieldData.' VarName '(indsel);'])
1193	end
1194	eval(['ProjData.' VarName '=griddata_uvmat(double(coord_X),double(coord_Y),double(FieldData.' VarName '),coord_x_proj,coord_y_proj'');'])
1195	eval(['varline=reshape(ProjData.' VarName ',1,length(coord_y_proj)*length(coord_x_proj));'])
1196	FFlag= isnan(varline); %detect undefined values NaN
1197	indnan=find(FFlag);
1198	if~isempty(indnan)
1199	varline(indnan)=zeros(size(indnan));
1200	eval(['ProjData.' VarName '=reshape(varline,length(coord_y_proj),length(coord_x_proj));'])
1201	FF(indnan)=ones(size(indnan));
1202	testFF=1;
1203	end
1204	if ivar==ivar_U
1205	ivar_U=ivar_new;
1206	end
1207	if ivar==ivar_V
1208	ivar_V=ivar_new;
1209	end
1210	if ivar==ivar_W
1211	ivar_W=ivar_new;
1212	end
1213	end
1214	end
1215	if testFF
1216	ProjData.FF=reshape(FF,length(coord_y_proj),length(coord_x_proj));
1217	ProjData.ListVarName=[ProjData.ListVarName {'FF'}];
1218	ProjData.VarDimName=[ProjData.VarDimName {DimCell}];
1219	ProjData.VarAttribute{ivar_new+1+nbcoord}.Role='errorflag';
1220	end
1221	end
1222	%case of fields defined on a structured grid
1223	else
1224	AYName=FieldData.ListVarName{VarType.coord(1)};
1225	AXName=FieldData.ListVarName{VarType.coord(2)};
1226	eval(['AX=FieldData.' AXName ';'])
1227	eval(['AY=FieldData.' AYName ';'])
1228	VarName=FieldData.ListVarName{VarIndex(1)};
1229	eval(['DimValue=size(FieldData.' VarName ');'])
1230	ListDimName=FieldData.VarDimName{VarIndex(1)};
1231	ProjData.ListVarName=[{AYName} {AXName} ProjData.ListVarName]; %TODO: check if it already exists in Projdata (several cells)
1232	ProjData.VarDimName=[{AYName} {AXName} ProjData.VarDimName];
1233	nbcolor=1; %default
1234	for idim=1:length(ListDimName)
1235	DimName=ListDimName{idim};
1236	if isequal(DimName,'rgb')\|isequal(DimName,'nb_coord')\|isequal(DimName,'nb_coord_i')
1237	nbcolor=DimValue(idim);
1238	DimIndices(idim)=[];
1239	DimValue(idim)=[];
1240	end
1241	if isequal(DimName,'nb_coord_j')% NOTE: CASE OF TENSOR NOT TREATED
1242	DimIndices(idim)=[];
1243	DimValue(idim)=[];
1244	end
1245	end
1246	ind_1=find(DimValue==1);
1247	DimIndices(ind_1)=[]; %suppress singleton dimensions
1248	% indxy=find(DimVarIndex(DimIndices));%select dimension variables (DimIndices non zero)
1249	nb_dim=length(DimIndices);%number of space dimensions
1250	Coord_z=[];
1251	Coord_y=[];
1252	Coord_x=[];
1253
1254	for idim=1:nb_dim %loop on space dimensions
1255	test_interp(idim)=0;%test for coordiate interpolation (non regular grid), =0 by default
1256	test_coord(idim)=0;%test for defined coordinates, =0 by default
1257	ivar=DimVarIndex(DimIndices(idim));% index of the variable corresponding to the current dimension
1258	if ~isequal(ivar,0)% a variable corresponds to the current dimension
1259	eval(['Coord{idim}=FieldData.' FieldData.ListVarName{ivar} ';']) ;% position for the first index
1260	DCoord=diff(Coord{idim});
1261	DCoord_min(idim)=min(DCoord);
1262	DCoord_max=max(DCoord);
1263	test_direct(idim)=DCoord_max>0;% =1 for increasing values, 0 otherwise
1264	test_direct_min=DCoord_min(idim)>0;% =1 for increasing values, 0 otherwise
1265	if ~isequal(test_direct(idim),test_direct_min)
1266	msgbox_uvmat('ERROR',['non monotonic dimension variable # ' num2str(idim) ' in proj_field.m'])
1267	return
1268	end
1269	test_interp(idim)=(DCoord_max-DCoord_min(idim))> 0.0001*abs(DCoord_max);% test grid regularity
1270	test_coord(idim)=1;
1271
1272	else % no variable associated with the first dimension, look for variable attributes Coord_1, _2 or _3
1273	Coord_i_str=['Coord_' num2str(idim)];
1274	DCoord_min(idim)=1;%default
1275	Coord{idim}=[0.5 DimValue(idim)-0.5];
1276	test_direct(idim)=1;
1277	end
1278	end
1279	if nb_dim==2
1280	if DY==0
1281	DY=abs(DCoord_min(1));
1282	end
1283	npY=1+round(abs(Coord{1}(end)-Coord{1}(1))/DY);%nbre of points after interpolation
1284	npy=1+round(abs(Coord{1}(end)-Coord{1}(1))/abs(DCoord_min(1)));%nbre of points after possible interpolation on a regular grid
1285	if DX==0
1286	DX=abs(DCoord_min(2));
1287	end
1288	npX=1+round(abs(Coord{2}(end)-Coord{2}(1))/DX);%nbre of points after interpol
1289	npx=1+round(abs(Coord{2}(end)-Coord{2}(1))/abs(DCoord_min(2)));%nbre of points after possible interpolation on a regular grid
1290	Coord_y=linspace(Coord{1}(1),Coord{1}(end),npY);
1291	test_direct_y=test_direct(1);
1292	Coord_x=linspace(Coord{2}(1),Coord{2}(end),npX);
1293	test_direct_x=test_direct(2);
1294	DAX=DCoord_min(2);
1295	DAY=DCoord_min(1);
1296	elseif nb_dim==3
1297	DZ=abs(DCoord_min(1));
1298	npz=1+round(abs(Coord{1}(end)-Coord{1}(1))/DZ);%nbre of points after interpolation
1299	if DY==0
1300	DY=abs(DCoord_min(2));
1301	end
1302	npY=1+round(abs(Coord{2}(end)-Coord{2}(1))/DY);%nbre of points after interpol
1303	npy=1+round(abs(Coord{2}(end)-Coord{2}(1))/abs(DCoord_min(2)));%nbre of points before interpol
1304	if DX==0
1305	DX=abs(DCoord_min(3));
1306	end
1307	npX=1+round(abs(Coord{3}(end)-Coord{3}(1))/DX);%nbre of points after interpol
1308	npx=1+round(abs(Coord{3}(end)-Coord{3}(1))/abs(DCoord_min(3)));%nbre of points before interpol
1309	Coord_z=linspace(Coord{1}(1),Coord{1}(end),npz);
1310	test_direct_z=test_direct(1);
1311	Coord_y=linspace(Coord{2}(1),Coord{2}(end),npY);
1312	test_direct_y=test_direct(2);
1313	Coord_x=linspace(Coord{3}(1),Coord{3}(end),npX);
1314	test_direct_x=test_direct(3);
1315	end
1316	minAX=min(Coord_x);
1317	maxAX=max(Coord_x);
1318	minAY=min(Coord_y);
1319	maxAY=max(Coord_y);
1320	xcorner=[minAX maxAX minAX maxAX]-ObjectData.Coord(1,1);
1321	ycorner=[maxAY maxAY minAY minAY]-ObjectData.Coord(1,2);
1322	xcor_new=xcornercos(Phi)+ycornersin(Phi);%coord new frame
1323	ycor_new=-xcornersin(Phi)+ycornercos(Phi);
1324	if ~testXMax
1325	XMax=max(xcor_new);
1326	end
1327	if ~testXMin
1328	XMin=min(xcor_new);
1329	end
1330	if ~testYMax
1331	YMax=max(ycor_new);
1332	end
1333	if ~testYMin
1334	YMin=min(ycor_new);
1335	end
1336	DXinit=(maxAX-minAX)/(npx-1);
1337	DYinit=(maxAY-minAY)/(npy-1);
1338	if DX==0
1339	DX=DXinit;
1340	end
1341	if DY==0
1342	DY=DYinit;
1343	end
1344	npX=floor((XMax-XMin)/DX+1);
1345	npY=floor((YMax-YMin)/DY+1);
1346	if test_direct_y
1347	coord_y_proj=linspace(YMin,YMax,npY);%abscissa of the new pixels along the line
1348	else
1349	coord_y_proj=linspace(YMax,YMin,npY);%abscissa of the new pixels along the line
1350	end
1351	if test_direct_x
1352	coord_x_proj=linspace(XMin,XMax,npX);%abscissa of the new pixels along the line
1353	else
1354	coord_x_proj=linspace(XMax,XMin,npX);%abscissa of the new pixels along the line
1355	end
1356
1357	% case with no rotation and interpolation
1358	if isequal(ProjMode,'projection') && isequal(Phi,0) && isequal(Theta,0) && isequal(Psi,0)
1359	if test_direct(1)
1360	min_ind1=ceil((YMin-Coord{1}(1))/DYinit)+1;
1361	max_ind1=floor((YMax-Coord{1}(1))/DYinit)+1;
1362	Ybound(1)=Coord{1}(1)+DYinit*(min_ind1-1);
1363	Ybound(2)=Coord{1}(1)+DYinit*(max_ind1-1);
1364	else
1365	min_ind1=ceil((Coord{1}(1)-YMax)/DYinit)+1;
1366	max_ind1=floor((Coord{1}(1)-YMin)/DYinit)+1;
1367	Ybound(2)=Coord{1}(1)-DYinit*(max_ind1-1);
1368	Ybound(1)=Coord{1}(1)-DYinit*(min_ind1-1);
1369	end
1370	if test_direct(2)==1
1371	min_ind2=ceil((XMin-Coord{2}(1))/DXinit)+1;
1372	max_ind2=floor((XMax-Coord{2}(1))/DXinit)+1;
1373	Xbound(1)=Coord{2}(1)+DXinit*(min_ind2-1);
1374	Xbound(2)=Coord{2}(1)+DXinit*(max_ind2-1);
1375	else
1376	min_ind2=ceil((Coord{2}(1)-XMax)/DXinit)+1;
1377	max_ind2=floor((Coord{2}(1)-XMin)/DXinit)+1;
1378	Xbound(2)=Coord{2}(1)+DXinit*(max_ind2-1);
1379	Xbound(1)=Coord{2}(1)+DXinit*(min_ind2-1);
1380	end
1381	min_ind1=max(min_ind1,1);% deals with margin (bound lower than the first index)
1382	min_ind2=max(min_ind2,1);
1383	max_ind1=min(max_ind1,npy);
1384	max_ind2=min(max_ind2,npx);
1385	for ivar=VarIndex
1386	VarName=FieldData.ListVarName{ivar};
1387	ProjData.ListVarName=[ProjData.ListVarName VarName];
1388	ProjData.VarDimIndex=[ProjData.VarDimIndex [nb_dim-1 nb_dim]];
1389	if length(FieldData.VarAttribute)>=ivar
1390	ProjData.VarAttribute{length(ProjData.ListVarName)}=FieldData.VarAttribute{ivar};
1391	end
1392	eval(['ProjData.' VarName '=FieldData.' VarName '(min_ind1:max_ind1,min_ind2:max_ind2) ;']);
1393	end
1394	else
1395	% case with rotation and/or interpolation
1396	if isempty(Coord_z) %2D case
1397	[X,Y]=meshgrid(coord_x_proj,coord_y_proj);%grid in the new coordinates
1398	XIMA=ObjectData.Coord(1,1)+(X)cos(Phi)-Ysin(Phi);%corresponding coordinates in the original image
1399	YIMA=ObjectData.Coord(1,2)+(X)sin(Phi)+Ycos(Phi);
1400	XIMA=(XIMA-minAX)/DXinit+1;% image index along x
1401	YIMA=(-YIMA+maxAY)/DYinit+1;% image index along y
1402	XIMA=reshape(round(XIMA),1,npX*npY);%indices reorganized in 'line'
1403	YIMA=reshape(round(YIMA),1,npX*npY);
1404	flagin=XIMA>=1 & XIMA<=npx & YIMA >=1 & YIMA<=npy;%flagin=1 inside the original image
1405	if isequal(ObjectData.ProjMode,'filter')
1406	npx_filter=ceil(abs(DX/DAX));
1407	npy_filter=ceil(abs(DY/DAY));
1408	Mfilter=ones(npy_filter,npx_filter)/(npx_filter*npy_filter);
1409	test_filter=1;
1410	else
1411	test_filter=0;
1412	end
1413	for ivar=VarIndex
1414	VarName=FieldData.ListVarName{ivar} ;
1415	if test_interp(1) \| test_interp(2)%interpolate on a regular grid
1416	eval(['FieldData.' VarName '=interp2(Coord{2},Coord{1},FieldData.' VarName ',Coord_x,Coord_y'');']) %TO TEST
1417	end
1418	%filter the field (image) if option 'filter' is used
1419	if test_filter
1420	Aclass=class(FieldData.A);
1421	eval(['FieldData.' VarName '=filter2(Mfilter,FieldData.' VarName ',''valid'');'])
1422	if ~isequal(Aclass,'double')
1423	eval(['FieldData.' VarName '=' Aclass '(FieldData.' VarName ');'])%revert to integer values
1424	end
1425	end
1426	eval(['vec_A=reshape(FieldData.' VarName ',npx*npy,nbcolor);'])%put the original image in line
1427	ind_in=find(flagin);
1428	ind_out=find(~flagin);
1429	ICOMB=(XIMA-1)*npy+YIMA;
1430	ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
1431	vec_B(ind_in,[1:nbcolor])=vec_A(ICOMB,:);
1432	for icolor=1:nbcolor
1433	vec_B(ind_out,icolor)=zeros(size(ind_out));
1434	end
1435	ProjData.ListVarName=[ProjData.ListVarName VarName];
1436	if length(FieldData.VarAttribute)>=ivar
1437	ProjData.VarAttribute{length(ProjData.ListVarName)+nbcoord}=FieldData.VarAttribute{ivar};
1438	end
1439	eval(['ProjData.' VarName '=reshape(vec_B,npY,npX,nbcolor);']);
1440	end
1441	ProjData.FF=reshape(~flagin,npY,npX);%false flag A FAIRE: tenir compte d'un flga antérieur
1442	ProjData.ListVarName=[ProjData.ListVarName 'FF'];
1443	ProjData.VarAttribute{length(ProjData.ListVarName)}.Role='errorflag';
1444	else %3D case
1445	if isequal(Theta,0) & isequal(Phi,0)
1446	test_sup=(Coord{1}>=ObjectData.Coord(1,3));
1447	iz_sup=find(test_sup);
1448	iz=iz_sup(1);
1449	if iz>=1 & iz<=npz
1450	ProjData.ListDimName=[ProjData.ListDimName ListDimName(2:end)];
1451	ProjData.DimValue=[ProjData.DimValue npY npX];
1452	for ivar=VarIndex
1453	VarName=FieldData.ListVarName{ivar};
1454	ProjData.ListVarName=[ProjData.ListVarName VarName];
1455	ProjData.VarAttribute{length(ProjData.ListVarName)}=FieldData.VarAttribute{ivar}; %reproduce the variable attributes
1456	eval(['ProjData.' VarName '=squeeze(FieldData.' VarName '(iz,:,:));'])% select the z index iz
1457	%TODO : do a vertical average for a thick plane
1458	if test_interp(2) \| test_interp(3)
1459	eval(['ProjData.' VarName '=interp2(Coord{3},Coord{2},ProjData.' VarName ',Coord_x,Coord_y'');'])
1460	end
1461	end
1462	end
1463	else
1464	errormsg='projection of structured coordinates on oblique plane not yet implemented';
1465	%TODO: use interp3
1466	return
1467	end
1468	end
1469	end
1470	end
1471	%projection of velocity components in the rotated coordinates
1472	if ~isequal(Phi,0) && length(ivar_U)==1
1473	if isempty(ivar_V)
1474	msgbox_uvmat('ERROR','v velocity component missing in proj_field.m')
1475	return
1476	end
1477	UName=FieldData.ListVarName{ivar_U};
1478	VName=FieldData.ListVarName{ivar_V};
1479	eval(['ProjData.' UName '=cos(Phi)ProjData.' UName '+ sin(Phi)ProjData.' VName ';'])
1480	eval(['ProjData.' VName '=cos(Theta)(-sin(Phi)ProjData.' UName '+ cos(Phi)*ProjData.' VName ');'])
1481	if ~isempty(ivar_W)
1482	WName=FieldData.ListVarName{ivar_W};
1483	eval(['ProjData.' VName '=ProjData.' VName '+ ProjData.' WName '*sin(Theta);'])%
1484	eval(['ProjData.' WName '=NormVec_XProjData.' UName '+ NormVec_YProjData.' VName '+ NormVec_Z* ProjData.' WName ';']);
1485	end
1486	if ~isequal(Psi,0)
1487	eval(['ProjData.' UName '=cos(Psi)* ProjData.' UName '- sin(Psi)*ProjData.' VName ';']);
1488	eval(['ProjData.' VName '=sin(Psi)* ProjData.' UName '+ cos(Psi)*ProjData.' VName ';']);
1489	end
1490	end
1491	end
1492
1493	%-----------------------------------------------------------------
1494	%project in a volume
1495	% A FAIRE ....(copie de proj_plane)
1496	function [ProjData,errormsg] = proj_volume(FieldData, ObjectData)
1497	%-----------------------------------------------------------------
1498
1499	%initialisation of the input parameters of the projection plane
1500	%-----------------------------------------------------------------
1501	ProjMode='projection';%direct projection by default
1502	if isfield(ObjectData,'ProjMode'),ProjMode=ObjectData.ProjMode; end;
1503
1504	%axis origin
1505	if isempty(ObjectData.Coord)
1506	ObjectData.Coord(1,1)=0;%origin of the volume set to [0 0] by default
1507	ObjectData.Coord(1,2)=0;
1508	ObjectData.Coord(1,3)=0;
1509	end
1510
1511	%rotation angles
1512	Phi=0;%default
1513	Theta=0;
1514	Psi=0;
1515	if isfield(ObjectData,'Phi')&& ~isempty(ObjectData.Phi)
1516	Phi=(pi/180)*ObjectData.Phi;%first Euler angle in radian
1517	end
1518	if isfield(ObjectData,'Theta')&& ~isempty(ObjectData.Theta)
1519	Theta=(pi/180)*ObjectData.Theta;%second Euler angle in radian
1520	end
1521	if isfield(ObjectData,'Psi')&& ~isempty(ObjectData.Psi)
1522	Psi=(pi/180)*ObjectData.Psi;%third Euler angle in radian
1523	end
1524
1525	%components of the unity vector normal to the projection plane
1526	NormVec_X=-sin(Phi)*sin(Theta);
1527	NormVec_Y=cos(Phi)*sin(Theta);
1528	NormVec_Z=cos(Theta);
1529
1530	% test for 3D fields
1531	test3D=0;
1532	if isfield(FieldData,'nb_dim')
1533	test3D=isequal(FieldData.nb_dim,3);
1534	end
1535	test3C=test3D; %default 3 vel components
1536
1537	%mesh sizes DX and DY
1538	DX=0;
1539	DY=0; %default
1540	if isfield(ObjectData,'DX')&~isempty(ObjectData.DX)
1541	DX=abs(ObjectData.DX);%mesh of interpolation points
1542	end
1543	if isfield(ObjectData,'DY')&~isempty(ObjectData.DY)
1544	DY=abs(ObjectData.DY);%mesh of interpolation points
1545	end
1546	if ~isequal(ProjMode,'projection') & (DX==0\|DY==0)
1547	errormsg='DX or DY missing';
1548	display(errormsg)
1549	return
1550	end
1551	if isfield(ObjectData,'DZ')&~isempty(ObjectData.DZ)
1552	DZ=abs(ObjectData.DZ);%mesh of interpolation points
1553	end
1554
1555	%extrema along each axis
1556	testXMin=0;
1557	testXMax=0;
1558	testYMin=0;
1559	testYMax=0;
1560	if isfield(ObjectData,'RangeX')
1561	XMin=min(ObjectData.RangeX);
1562	XMax=max(ObjectData.RangeX);
1563	testXMin=XMax>XMin;
1564	testXMax=1;
1565	end
1566	if isfield(ObjectData,'RangeY')
1567	YMin=min(ObjectData.RangeY);
1568	YMax=max(ObjectData.RangeY);
1569	testYMin=YMax>YMin;
1570	testYMax=1;
1571	end
1572	width=0;%default width of the projection band
1573	if isfield(ObjectData,'RangeZ')
1574	ZMin=min(ObjectData.RangeZ);
1575	ZMax=max(ObjectData.RangeZ);
1576	testZMin=YMax>YMin;
1577	testZMax=1;
1578	% width=max(ObjectData.RangeZ);
1579	end
1580
1581	% initiate Matlab structure for physical field
1582	ProjData=proj_heading(FieldData,ObjectData);
1583	ProjData.NbDim=3;
1584	ProjData.ListDimName={};%name of dimension
1585	ProjData.DimValue=[];%values of dimension (nbre of vectors)
1586	ProjData.ListVarName={};
1587	ProjData.VarDimName={};
1588
1589	error=0;%default
1590	flux=0;
1591	testfalse=0;
1592	ListIndex={};
1593
1594	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
1595	%group the variables (fields of 'FieldData') in cells of variables with the same dimensions
1596	%-----------------------------------------------------------------
1597	idimvar=0;
1598	[CellVarIndex,NbDim,VarTypeCell,errormsg]=find_field_indices(FieldData);
1599	if ~isempty(errormsg)
1600	errormsg=['error in proj_field/proj_plane:' errormsg];
1601	return
1602	end
1603	%LOOP ON GROUPS OF VARIABLES SHARING THE SAME DIMENSIONS
1604	% CellVarIndex=cells of variable index arrays
1605	ivar_new=0; % index of the current variable in the projected field
1606	icoord=0;
1607	nbcoord=0;%number of added coordinate variables brought by projection
1608	for icell=1:length(CellVarIndex)
1609	if NbDim(icell)<2
1610	continue
1611	end
1612	VarIndex=CellVarIndex{icell};% indices of the selected variables in the list FieldData.ListVarName
1613	VarType=VarTypeCell{icell};
1614	ivar_X=VarType.coord_x;
1615	ivar_Y=VarType.coord_y;
1616	ivar_Z=VarType.coord_z;
1617	ivar_U=VarType.vector_x;
1618	ivar_V=VarType.vector_y;
1619	ivar_W=VarType.vector_z;
1620	ivar_C=VarType.scalar ;
1621	ivar_Anc=VarType.ancillary;
1622	test_anc=zeros(size(VarIndex));
1623	test_anc(ivar_Anc)=ones(size(ivar_Anc));
1624	ivar_F=VarType.warnflag;
1625	ivar_FF=VarType.errorflag;
1626	testX=~isempty(ivar_X) && ~isempty(ivar_Y);
1627	DimCell=FieldData.VarDimName{VarIndex(1)};
1628	if ischar(DimCell)
1629	DimCell={DimCell};%name of dimensions
1630	end
1631
1632	%case of input fields with unstructured coordinates
1633	if testX
1634	XName=FieldData.ListVarName{ivar_X};
1635	YName=FieldData.ListVarName{ivar_Y};
1636	eval(['coord_x=FieldData.' XName ';'])
1637	eval(['coord_y=FieldData.' YName ';'])
1638	if length(ivar_Z)==1
1639	ZName=FieldData.ListVarName{ivar_Z};
1640	eval(['coord_z=FieldData.' ZName ';'])
1641	end
1642
1643	% translate initial coordinates
1644	coord_x=coord_x-ObjectData.Coord(1,1);
1645	coord_y=coord_y-ObjectData.Coord(1,2);
1646	if ~isempty(ivar_Z)
1647	coord_z=coord_z-ObjectData.Coord(1,3);
1648	end
1649
1650	% selection of the vectors in the projection range (3D case)
1651	if length(ivar_Z)==1 && width > 0
1652	%components of the unitiy vector normal to the projection plane
1653	fieldZ=NormVec_Xcoord_x + NormVec_Ycoord_y+ NormVec_Z*coord_z;% distance to the plane
1654	indcut=find(abs(fieldZ) <= width);
1655	for ivar=VarIndex
1656	VarName=FieldData.ListVarName{ivar};
1657	eval(['FieldData.' VarName '=FieldData.' VarName '(indcut);'])
1658	% end
1659	% A VOIR : CAS DE VAR STRUCTUREE MAIS PAS GRILLE REGULIERE : INTERPOLER SUR GRILLE REGULIERE
1660	end
1661	coord_x=coord_x(indcut);
1662	coord_y=coord_y(indcut);
1663	coord_z=coord_z(indcut);
1664	end
1665
1666	%rotate coordinates if needed
1667	if isequal(Phi,0)
1668	coord_X=coord_x;
1669	coord_Y=coord_y;
1670	if ~isequal(Theta,0)
1671	coord_Y=coord_Y *cos(Theta);
1672	end
1673	else
1674	coord_X=(coord_x cos(Phi) + coord_y sin(Phi));
1675	coord_Y=(-coord_x sin(Phi) + coord_y cos(Phi))*cos(Theta);
1676	end
1677	if ~isempty(ivar_Z)
1678	coord_Y=coord_Y+coord_z *sin(Theta);
1679	end
1680	if ~isequal(Psi,0)
1681	coord_X=(coord_X cos(Psi) - coord_Y sin(Psi));%A VERIFIER
1682	coord_Y=(coord_X sin(Psi) + coord_Y cos(Psi));
1683	end
1684	coord_Z=coord_z; %TO UPDATE
1685	%restriction to the range of x and y if imposed
1686	testin=ones(size(coord_X)); %default
1687	testbound=0;
1688	if testXMin
1689	testin=testin & (coord_X >= XMin);
1690	testbound=1;
1691	end
1692	if testXMax
1693	testin=testin & (coord_X <= XMax);
1694	testbound=1;
1695	end
1696	if testYMin
1697	testin=testin & (coord_Y >= YMin);
1698	testbound=1;
1699	end
1700	if testYMin
1701	testin=testin & (coord_Y <= YMax);
1702	testbound=1;
1703	end
1704	if testbound
1705	indcut=find(testin);
1706	for ivar=VarIndex
1707	VarName=FieldData.ListVarName{ivar};
1708	eval(['FieldData.' VarName '=FieldData.' VarName '(indcut);'])
1709	end
1710	coord_X=coord_X(indcut);
1711	coord_Y=coord_Y(indcut);
1712	if length(ivar_Z)==1
1713	coord_Z=coord_Z(indcut);
1714	end
1715	end
1716	% different cases of projection
1717	if isequal(ObjectData.ProjMode,'projection')
1718	%the list of dimension
1719	ProjData.ListDimName=[ProjData.ListDimName FieldData.VarDimName(VarIndex(1))];%add the point index to the list of dimensions
1720	ProjData.DimValue=[ProjData.DimValue length(coord_X)];
1721	nbvar=0;
1722	for ivar=VarIndex %transfer variables to the projection plane
1723	VarName=FieldData.ListVarName{ivar};
1724	if ivar==ivar_X %x coordinate
1725	eval(['ProjData.' VarName '=coord_X;'])
1726	elseif ivar==ivar_Y % y coordinate
1727	eval(['ProjData.' VarName '=coord_Y;'])
1728	elseif isempty(ivar_Z) \|\| ivar~=ivar_Z % other variables (except Z coordinate wyhich is not reproduced)
1729	eval(['ProjData.' VarName '=FieldData.' VarName ';'])
1730	end
1731	if isempty(ivar_Z) \|\| ivar~=ivar_Z
1732	ProjData.ListVarName=[ProjData.ListVarName VarName];
1733	ProjData.VarDimName=[ProjData.VarDimName DimCell];
1734	nbvar=nbvar+1;
1735	if isfield(FieldData,'VarAttribute') & length(FieldData.VarAttribute) >=ivar
1736	ProjData.VarAttribute{nbvar}=FieldData.VarAttribute{ivar};
1737	end
1738	end
1739	end
1740	elseif isequal(ObjectData.ProjMode,'interp')\|\|isequal(ObjectData.ProjMode,'filter')%interpolate data on a regular grid
1741	coord_x_proj=[XMin:DX:XMax];
1742	coord_y_proj=[YMin:DY:YMax];
1743	coord_z_proj=[ZMin:DZ:ZMax];
1744	[XI,YI,ZI]=meshgrid(coord_x_proj,coord_y_proj,coord_z_proj);
1745	DimCell={'coord_y','coord_x'};
1746	ProjData.ListVarName={'coord_z','coord_y','coord_x'};
1747	ProjData.VarDimName={'coord_z','coord_y','coord_x'};
1748	nbcoord=3;
1749	ProjData.coord_z=[ZMin ZMax];
1750	ProjData.coord_y=[YMin YMax];
1751	ProjData.coord_x=[XMin XMax];
1752	if isempty(ivar_X), ivar_X=0; end;
1753	if isempty(ivar_Y), ivar_Y=0; end;
1754	if isempty(ivar_Z), ivar_Z=0; end;
1755	if isempty(ivar_U), ivar_U=0; end;
1756	if isempty(ivar_V), ivar_V=0; end;
1757	if isempty(ivar_W), ivar_W=0; end;
1758	if isempty(ivar_F), ivar_F=0; end;
1759	if isempty(ivar_FF), ivar_FF=0; end;
1760	if ~isequal(ivar_FF,0)
1761	VarName_FF=FieldData.ListVarName{ivar_FF};
1762	eval(['indsel=find(FieldData.' VarName_FF '==0);'])
1763	coord_X=coord_X(indsel);
1764	coord_Y=coord_Y(indsel);
1765	end
1766	FF=zeros(1,length(coord_y_proj)*length(coord_x_proj));
1767	testFF=0;
1768	size(XI)
1769	size(YI)
1770	size(ZI)
1771	for ivar=VarIndex
1772	VarName=FieldData.ListVarName{ivar};
1773	if ~( ivar==ivar_X \|\| ivar==ivar_Y \|\| ivar==ivar_Z \|\| ivar==ivar_F \|\| ivar==ivar_FF \|\| test_anc(ivar)==1)
1774	ivar_new=ivar_new+1;
1775	ProjData.ListVarName=[ProjData.ListVarName {VarName}];
1776	ProjData.VarDimName=[ProjData.VarDimName {DimCell}];
1777	if isfield(FieldData,'VarAttribute') && length(FieldData.VarAttribute) >=ivar
1778	ProjData.VarAttribute{ivar_new+nbcoord}=FieldData.VarAttribute{ivar};
1779	end
1780	if ~isequal(ivar_FF,0)
1781	eval(['FieldData.' VarName '=FieldData.' VarName '(indsel);'])
1782	end
1783	eval(['ProjData.' VarName '=griddata3(double(coord_X),double(coord_Y),double(coord_Z),double(FieldData.' VarName '),XI,YI,ZI);'])
1784	% eval(['varline=reshape(ProjData.' VarName ',1,length(coord_y_proj)*length(coord_x_proj));'])
1785	% FFlag= isnan(varline); %detect undefined values NaN
1786	% indnan=find(FFlag);
1787	% if~isempty(indnan)
1788	% varline(indnan)=zeros(size(indnan));
1789	% eval(['ProjData.' VarName '=reshape(varline,length(coord_y_proj),length(coord_x_proj));'])
1790	% FF(indnan)=ones(size(indnan));
1791	% testFF=1;
1792	% end
1793	% if ivar==ivar_U
1794	% ivar_U=ivar_new;
1795	% end
1796	% if ivar==ivar_V
1797	% ivar_V=ivar_new;
1798	% end
1799	% if ivar==ivar_W
1800	% ivar_W=ivar_new;
1801	% end
1802	end
1803	end
1804	if testFF
1805	ProjData.FF=reshape(FF,length(coord_y_proj),length(coord_x_proj));
1806	ProjData.ListVarName=[ProjData.ListVarName {'FF'}];
1807	ProjData.VarDimName=[ProjData.VarDimName {DimCell}];
1808	ProjData.VarAttribute{ivar_new+1+nbcoord}.Role='errorflag';
1809	end
1810	end
1811	%case of fields defined on a structured grid
1812	else
1813	AYName=FieldData.ListVarName{VarType.coord(1)};
1814	AXName=FieldData.ListVarName{VarType.coord(2)};
1815	eval(['AX=FieldData.' AXName ';'])
1816	eval(['AY=FieldData.' AYName ';'])
1817	VarName=FieldData.ListVarName{VarIndex(1)};
1818	eval(['DimValue=size(FieldData.' VarName ');'])
1819	ListDimName=FieldData.VarDimName{VarIndex(1)};
1820	ProjData.ListVarName=[{AYName} {AXName} ProjData.ListVarName]; %TODO: check if it already exists in Projdata (several cells)
1821	ProjData.VarDimName=[{AYName} {AXName} ProjData.VarDimName];
1822	nbcolor=1; %default
1823	for idim=1:length(ListDimName)
1824	DimName=ListDimName{idim};
1825	if isequal(DimName,'rgb')\|isequal(DimName,'nb_coord')\|isequal(DimName,'nb_coord_i')
1826	nbcolor=DimValue(idim);
1827	DimIndices(idim)=[];
1828	DimValue(idim)=[];
1829	end
1830	if isequal(DimName,'nb_coord_j')% NOTE: CASE OF TENSOR NOT TREATED
1831	DimIndices(idim)=[];
1832	DimValue(idim)=[];
1833	end
1834	end
1835	ind_1=find(DimValue==1);
1836	DimIndices(ind_1)=[]; %suppress singleton dimensions
1837	% indxy=find(DimVarIndex(DimIndices));%select dimension variables (DimIndices non zero)
1838	nb_dim=length(DimIndices);%number of space dimensions
1839	Coord_z=[];
1840	Coord_y=[];
1841	Coord_x=[];
1842
1843	for idim=1:nb_dim %loop on space dimensions
1844	test_interp(idim)=0;%test for coordiate interpolation (non regular grid), =0 by default
1845	test_coord(idim)=0;%test for defined coordinates, =0 by default
1846	ivar=DimVarIndex(DimIndices(idim));% index of the variable corresponding to the current dimension
1847	if ~isequal(ivar,0)% a variable corresponds to the current dimension
1848	eval(['Coord{idim}=FieldData.' FieldData.ListVarName{ivar} ';']) ;% position for the first index
1849	DCoord=diff(Coord{idim});
1850	DCoord_min(idim)=min(DCoord);
1851	DCoord_max=max(DCoord);
1852	test_direct(idim)=DCoord_max>0;% =1 for increasing values, 0 otherwise
1853	test_direct_min=DCoord_min(idim)>0;% =1 for increasing values, 0 otherwise
1854	if ~isequal(test_direct(idim),test_direct_min)
1855	msgbox_uvmat('ERROR',['non monotonic dimension variable # ' num2str(idim) ' in proj_field.m'])
1856	return
1857	end
1858	test_interp(idim)=(DCoord_max-DCoord_min(idim))> 0.0001*abs(DCoord_max);% test grid regularity
1859	test_coord(idim)=1;
1860
1861	else % no variable associated with the first dimension, look for variable attributes Coord_1, _2 or _3
1862	Coord_i_str=['Coord_' num2str(idim)];
1863	DCoord_min(idim)=1;%default
1864	Coord{idim}=[0.5 DimValue(idim)-0.5];
1865	test_direct(idim)=1;
1866	end
1867	end
1868	if nb_dim==2
1869	if DY==0
1870	DY=abs(DCoord_min(1));
1871	end
1872	npY=1+round(abs(Coord{1}(end)-Coord{1}(1))/DY);%nbre of points after interpolation
1873	npy=1+round(abs(Coord{1}(end)-Coord{1}(1))/abs(DCoord_min(1)));%nbre of points after possible interpolation on a regular grid
1874	if DX==0
1875	DX=abs(DCoord_min(2));
1876	end
1877	npX=1+round(abs(Coord{2}(end)-Coord{2}(1))/DX);%nbre of points after interpol
1878	npx=1+round(abs(Coord{2}(end)-Coord{2}(1))/abs(DCoord_min(2)));%nbre of points after possible interpolation on a regular grid
1879	Coord_y=linspace(Coord{1}(1),Coord{1}(end),npY);
1880	test_direct_y=test_direct(1);
1881	Coord_x=linspace(Coord{2}(1),Coord{2}(end),npX);
1882	test_direct_x=test_direct(2);
1883	DAX=DCoord_min(2);
1884	DAY=DCoord_min(1);
1885	elseif nb_dim==3
1886	DZ=abs(DCoord_min(1));
1887	npz=1+round(abs(Coord{1}(end)-Coord{1}(1))/DZ);%nbre of points after interpolation
1888	if DY==0
1889	DY=abs(DCoord_min(2));
1890	end
1891	npY=1+round(abs(Coord{2}(end)-Coord{2}(1))/DY);%nbre of points after interpol
1892	npy=1+round(abs(Coord{2}(end)-Coord{2}(1))/abs(DCoord_min(2)));%nbre of points before interpol
1893	if DX==0
1894	DX=abs(DCoord_min(3));
1895	end
1896	npX=1+round(abs(Coord{3}(end)-Coord{3}(1))/DX);%nbre of points after interpol
1897	npx=1+round(abs(Coord{3}(end)-Coord{3}(1))/abs(DCoord_min(3)));%nbre of points before interpol
1898	Coord_z=linspace(Coord{1}(1),Coord{1}(end),npz);
1899	test_direct_z=test_direct(1);
1900	Coord_y=linspace(Coord{2}(1),Coord{2}(end),npY);
1901	test_direct_y=test_direct(2);
1902	Coord_x=linspace(Coord{3}(1),Coord{3}(end),npX);
1903	test_direct_x=test_direct(3);
1904	end
1905	minAX=min(Coord_x);
1906	maxAX=max(Coord_x);
1907	minAY=min(Coord_y);
1908	maxAY=max(Coord_y);
1909	xcorner=[minAX maxAX minAX maxAX]-ObjectData.Coord(1,1);
1910	ycorner=[maxAY maxAY minAY minAY]-ObjectData.Coord(1,2);
1911	xcor_new=xcornercos(Phi)+ycornersin(Phi);%coord new frame
1912	ycor_new=-xcornersin(Phi)+ycornercos(Phi);
1913	if ~testXMax
1914	XMax=max(xcor_new);
1915	end
1916	if ~testXMin
1917	XMin=min(xcor_new);
1918	end
1919	if ~testYMax
1920	YMax=max(ycor_new);
1921	end
1922	if ~testYMin
1923	YMin=min(ycor_new);
1924	end
1925	DXinit=(maxAX-minAX)/(npx-1);
1926	DYinit=(maxAY-minAY)/(npy-1);
1927	if DX==0
1928	DX=DXinit;
1929	end
1930	if DY==0
1931	DY=DYinit;
1932	end
1933	npX=floor((XMax-XMin)/DX+1);
1934	npY=floor((YMax-YMin)/DY+1);
1935	if test_direct_y
1936	coord_y_proj=linspace(YMin,YMax,npY);%abscissa of the new pixels along the line
1937	else
1938	coord_y_proj=linspace(YMax,YMin,npY);%abscissa of the new pixels along the line
1939	end
1940	if test_direct_x
1941	coord_x_proj=linspace(XMin,XMax,npX);%abscissa of the new pixels along the line
1942	else
1943	coord_x_proj=linspace(XMax,XMin,npX);%abscissa of the new pixels along the line
1944	end
1945
1946	% case with no rotation and interpolation
1947	if isequal(ProjMode,'projection') && isequal(Phi,0) && isequal(Theta,0) && isequal(Psi,0)
1948	if test_direct(1)
1949	min_ind1=ceil((YMin-Coord{1}(1))/DYinit)+1;
1950	max_ind1=floor((YMax-Coord{1}(1))/DYinit)+1;
1951	Ybound(1)=Coord{1}(1)+DYinit*(min_ind1-1);
1952	Ybound(2)=Coord{1}(1)+DYinit*(max_ind1-1);
1953	else
1954	min_ind1=ceil((Coord{1}(1)-YMax)/DYinit)+1;
1955	max_ind1=floor((Coord{1}(1)-YMin)/DYinit)+1;
1956	Ybound(2)=Coord{1}(1)-DYinit*(max_ind1-1);
1957	Ybound(1)=Coord{1}(1)-DYinit*(min_ind1-1);
1958	end
1959	if test_direct(2)==1
1960	min_ind2=ceil((XMin-Coord{2}(1))/DXinit)+1;
1961	max_ind2=floor((XMax-Coord{2}(1))/DXinit)+1;
1962	Xbound(1)=Coord{2}(1)+DXinit*(min_ind2-1);
1963	Xbound(2)=Coord{2}(1)+DXinit*(max_ind2-1);
1964	else
1965	min_ind2=ceil((Coord{2}(1)-XMax)/DXinit)+1;
1966	max_ind2=floor((Coord{2}(1)-XMin)/DXinit)+1;
1967	Xbound(2)=Coord{2}(1)+DXinit*(max_ind2-1);
1968	Xbound(1)=Coord{2}(1)+DXinit*(min_ind2-1);
1969	end
1970	min_ind1=max(min_ind1,1);% deals with margin (bound lower than the first index)
1971	min_ind2=max(min_ind2,1);
1972	max_ind1=min(max_ind1,npy);
1973	max_ind2=min(max_ind2,npx);
1974	for ivar=VarIndex
1975	VarName=FieldData.ListVarName{ivar};
1976	ProjData.ListVarName=[ProjData.ListVarName VarName];
1977	ProjData.VarDimIndex=[ProjData.VarDimIndex [nb_dim-1 nb_dim]];
1978	if length(FieldData.VarAttribute)>=ivar
1979	ProjData.VarAttribute{length(ProjData.ListVarName)}=FieldData.VarAttribute{ivar};
1980	end
1981	eval(['ProjData.' VarName '=FieldData.' VarName '(min_ind1:max_ind1,min_ind2:max_ind2) ;']);
1982	end
1983	else
1984	% case with rotation and/or interpolation
1985	if isempty(Coord_z) %2D case
1986	[X,Y]=meshgrid(coord_x_proj,coord_y_proj);%grid in the new coordinates
1987	XIMA=ObjectData.Coord(1,1)+(X)cos(Phi)-Ysin(Phi);%corresponding coordinates in the original image
1988	YIMA=ObjectData.Coord(1,2)+(X)sin(Phi)+Ycos(Phi);
1989	XIMA=(XIMA-minAX)/DXinit+1;% image index along x
1990	YIMA=(-YIMA+maxAY)/DYinit+1;% image index along y
1991	XIMA=reshape(round(XIMA),1,npX*npY);%indices reorganized in 'line'
1992	YIMA=reshape(round(YIMA),1,npX*npY);
1993	flagin=XIMA>=1 & XIMA<=npx & YIMA >=1 & YIMA<=npy;%flagin=1 inside the original image
1994	if isequal(ObjectData.ProjMode,'filter')
1995	npx_filter=ceil(abs(DX/DAX));
1996	npy_filter=ceil(abs(DY/DAY));
1997	Mfilter=ones(npy_filter,npx_filter)/(npx_filter*npy_filter);
1998	test_filter=1;
1999	else
2000	test_filter=0;
2001	end
2002	for ivar=VarIndex
2003	VarName=FieldData.ListVarName{ivar} ;
2004	if test_interp(1) \| test_interp(2)%interpolate on a regular grid
2005	eval(['FieldData.' VarName '=interp2(Coord{2},Coord{1},FieldData.' VarName ',Coord_x,Coord_y'');']) %TO TEST
2006	end
2007	%filter the field (image) if option 'filter' is used
2008	if test_filter
2009	Aclass=class(FieldData.A);
2010	eval(['FieldData.' VarName '=filter2(Mfilter,FieldData.' VarName ',''valid'');'])
2011	if ~isequal(Aclass,'double')
2012	eval(['FieldData.' VarName '=' Aclass '(FieldData.' VarName ');'])%revert to integer values
2013	end
2014	end
2015	eval(['vec_A=reshape(FieldData.' VarName ',npx*npy,nbcolor);'])%put the original image in line
2016	ind_in=find(flagin);
2017	ind_out=find(~flagin);
2018	ICOMB=(XIMA-1)*npy+YIMA;
2019	ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
2020	vec_B(ind_in,[1:nbcolor])=vec_A(ICOMB,:);
2021	for icolor=1:nbcolor
2022	vec_B(ind_out,icolor)=zeros(size(ind_out));
2023	end
2024	ProjData.ListVarName=[ProjData.ListVarName VarName];
2025	if length(FieldData.VarAttribute)>=ivar
2026	ProjData.VarAttribute{length(ProjData.ListVarName)+nbcoord}=FieldData.VarAttribute{ivar};
2027	end
2028	eval(['ProjData.' VarName '=reshape(vec_B,npY,npX,nbcolor);']);
2029	end
2030	ProjData.FF=reshape(~flagin,npY,npX);%false flag A FAIRE: tenir compte d'un flga antérieur
2031	ProjData.ListVarName=[ProjData.ListVarName 'FF'];
2032	ProjData.VarAttribute{length(ProjData.ListVarName)}.Role='errorflag';
2033	else %3D case
2034	if isequal(Theta,0) & isequal(Phi,0)
2035	test_sup=(Coord{1}>=ObjectData.Coord(1,3));
2036	iz_sup=find(test_sup);
2037	iz=iz_sup(1);
2038	if iz>=1 & iz<=npz
2039	ProjData.ListDimName=[ProjData.ListDimName ListDimName(2:end)];
2040	ProjData.DimValue=[ProjData.DimValue npY npX];
2041	for ivar=VarIndex
2042	VarName=FieldData.ListVarName{ivar};
2043	ProjData.ListVarName=[ProjData.ListVarName VarName];
2044	ProjData.VarAttribute{length(ProjData.ListVarName)}=FieldData.VarAttribute{ivar}; %reproduce the variable attributes
2045	eval(['ProjData.' VarName '=squeeze(FieldData.' VarName '(iz,:,:));'])% select the z index iz
2046	%TODO : do a vertical average for a thick plane
2047	if test_interp(2) \| test_interp(3)
2048	eval(['ProjData.' VarName '=interp2(Coord{3},Coord{2},ProjData.' VarName ',Coord_x,Coord_y'');'])
2049	end
2050	end
2051	end
2052	else
2053	errormsg='projection of structured coordinates on oblique plane not yet implemented';
2054	%TODO: use interp3
2055	return
2056	end
2057	end
2058	end
2059	end
2060	%projection of velocity components in the rotated coordinates
2061	if ~isequal(Phi,0) && length(ivar_U)==1
2062	if isempty(ivar_V)
2063	msgbox_uvmat('ERROR','v velocity component missing in proj_field.m')
2064	return
2065	end
2066	UName=FieldData.ListVarName{ivar_U};
2067	VName=FieldData.ListVarName{ivar_V};
2068	eval(['ProjData.' UName '=cos(Phi)ProjData.' UName '+ sin(Phi)ProjData.' VName ';'])
2069	eval(['ProjData.' VName '=cos(Theta)(-sin(Phi)ProjData.' UName '+ cos(Phi)*ProjData.' VName ');'])
2070	if ~isempty(ivar_W)
2071	WName=FieldData.ListVarName{ivar_W};
2072	eval(['ProjData.' VName '=ProjData.' VName '+ ProjData.' WName '*sin(Theta);'])%
2073	eval(['ProjData.' WName '=NormVec_XProjData.' UName '+ NormVec_YProjData.' VName '+ NormVec_Z* ProjData.' WName ';']);
2074	end
2075	if ~isequal(Psi,0)
2076	eval(['ProjData.' UName '=cos(Psi)* ProjData.' UName '- sin(Psi)*ProjData.' VName ';']);
2077	eval(['ProjData.' VName '=sin(Psi)* ProjData.' UName '+ cos(Psi)*ProjData.' VName ';']);
2078	end
2079	end
2080	end
2081
2082	%-----------------------------------------------------------------
2083	%transmit the global attributes
2084	function [ProjData,errormsg]=proj_heading(FieldData,ObjectData)
2085	%-----------------------------------------------------------------
2086	% ProjData=FieldData;
2087	ProjData=[];%default
2088	if ~isfield(FieldData,'ListGlobalAttribute')
2089	ProjData.ListGlobalAttribute={};
2090	else
2091	ProjData.ListGlobalAttribute=FieldData.ListGlobalAttribute;
2092	end
2093	if isfield(FieldData,'Txt')
2094	errormsg=FieldData.Txt; %transmit erreur message
2095	return;
2096	end
2097	for iattr=1:length(ProjData.ListGlobalAttribute)
2098	AttrName=ProjData.ListGlobalAttribute{iattr};
2099	if isfield(FieldData,AttrName)
2100	eval(['ProjData.' AttrName '=FieldData.' AttrName ';']);
2101	end
2102	end
2103	if isfield(FieldData,'CoordType')
2104	if isfield(ObjectData,'CoordType')&~isequal(FieldData.CoordType,ObjectData.CoordType)
2105	errormsg=[ObjectData.Style ' in ' ObjectData.CoordType ' coordinates, while field in ' FieldData.CoordType ' coordinates'];
2106	return
2107	else
2108	ProjData.CoordType=FieldData.CoordType;
2109	end
2110	end
2111
2112	ListObject={'Style','ProjMode','RangeX','RangeY','RangeZ','Phi','Theta','Psi','Coord'};
2113	for ilist=1:length(ListObject)
2114	if isfield(ObjectData,ListObject{ilist})
2115	eval(['val=ObjectData.' ListObject{ilist} ';'])
2116	if ~isempty(val)
2117	eval(['ProjData.Object' ListObject{ilist} '=val;']);
2118	ProjData.ListGlobalAttribute=[ProjData.ListGlobalAttribute {['Object' ListObject{ilist}]}];
2119	end
2120	end
2121	end

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