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source: trunk/src/transform_field/phys.m @ 79

Last change on this file since 79 was 79, checked in by sommeria, 14 years ago

time_series: subdir for result /time_series
mouse_motio: attempt to improve the circle marking vectors: use Visible off and on.
phys: bug repair for combining two images
set_oject: bug repair for creating new object
--This line those below, will be ignored--time_series

M src/series/time_series.m
M src/mouse_motion.m
M src/transform_field/phys.m
M src/set_object.m

File size: 11.9 KB

Line
1	%'phys': transforms image (px) to real world (phys) coordinates using geometric calibration parameters
2	% DataOut=phys(Data,CalibData) , transform one input field
3	% [DataOut,DataOut_1]=phys(Data,CalibData,Data_1,CalibData_1), transform two input fields
4
5	% OUTPUT:
6	% DataOut: structure representing the modified field
7	% DataOut_1: structure representing the second modified field
8
9	%INPUT:
10	% Data: structure of input data
11	% with fields .A (image or scalar matrix), AX, AY
12	% .X,.Y,.U,.V, .DjUi
13	% .ZIndex: index of plane in multilevel case
14	% .CoordType='phys' or 'px', The function ACTS ONLY IF .CoordType='px'
15	% CalibData: structure containing calibration parameters or a subtree Calib.GeometryCalib =calibration data (tsai parameters)
16
17	function [DataOut,DataOut_1]=phys(varargin)
18	% A FAIRE: 1- verifier si DataIn est une 'field structure'(.ListVarName'):
19	% chercher ListVarAttribute, for each field (cell of variables):
20	% .CoordType: 'phys' or 'px' (default==phys, no transform)
21	% .scale_factor: =dt (to transform displacement into velocity) default=1
22	% .covariance: 'scalar', 'coord', 'D_i': covariant (like velocity), 'D^i': contravariant (like gradient), 'D^jD_i' (like strain tensor)
23	% (default='coord' if .Role='coord_x,_y...,
24	% 'D_i' if '.Role='vector_x,...',
25	% 'scalar', else (thenno change except scale factor)
26	Calib{1}=[];
27	if nargin==2\|\|nargin==4 % nargin =nbre of input variables
28	Data=varargin{1};
29	DataOut=Data;%default
30	DataOut_1=[];%default
31	CalibData=varargin{2};
32	if isfield(CalibData,'GeometryCalib')
33	Calib{1}=CalibData.GeometryCalib;
34	end
35	Calib{2}=Calib{1};
36	else
37	DataOut.Txt='wrong input: need two or four structures';
38	end
39	test_1=0;
40	if nargin==4
41	test_1=1;
42	Data_1=varargin{3};
43	DataOut_1=Data_1;%default
44	CalibData_1=varargin{4};
45	if isfield(CalibData_1,'GeometryCalib')
46	Calib{2}=CalibData_1.GeometryCalib;
47	end
48	end
49	iscalar=0;
50	if ~isempty(Calib{1})
51	DataOut=phys_1(Data,Calib{1});
52	%case of images or scalar: in case of two input fields, we need to project the transform of on the same regular grid
53	if isfield(Data,'A') && isfield(Data,'AX') && ~isempty(Data.AX) && isfield(Data,'AY')&&...
54	~isempty(Data.AY) && length(Data.A)>1
55	iscalar=1;
56	A{1}=Data.A;
57	end
58	end
59	%transform of X,Y coordinates for vector fields
60	if isfield(Data,'ZIndex')&&~isempty(Data.ZIndex)
61	ZIndex=Data.ZIndex;
62	else
63	ZIndex=0;
64	end
65	if test_1
66	DataOut_1=phys_1(Data_1,Calib{2});
67	if isfield(Data_1,'A')&&isfield(Data_1,'AX')&&~isempty(Data_1.AX) && isfield(Data_1,'AY')&&...
68	~isempty(Data_1.AY)&&length(Data_1.A)>1
69	iscalar=iscalar+1;
70	Calib{iscalar}=Calib{2};
71	A{iscalar}=Data_1.A;
72	if isfield(Data_1,'ZIndex') && ~isequal(Data_1.ZIndex,ZIndex)
73	DataOut.Txt='inconsistent plane indexes in the two input fields';
74	end
75	if iscalar==1% case for which only the second field is a scalar
76	[A,AX,AY]=phys_Ima(A,Calib,ZIndex);
77	DataOut_1.A=A{1};
78	DataOut_1.AX=AX;
79	DataOut_1.AY=AY;
80	return
81	end
82	end
83	end
84	if iscalar~=0
85	[A,AX,AY]=phys_Ima(A,Calib,ZIndex);%TODO : introduire interp2_uvmat ds phys_ima
86	DataOut.A=A{1};
87	DataOut.AX=AX;
88	DataOut.AY=AY;
89	if iscalar==2
90	DataOut_1.A=A{2};
91	DataOut_1.AX=AX;
92	DataOut_1.AY=AY;
93	end
94	end
95
96	%------------------------------------------------
97	function DataOut=phys_1(Data,Calib)
98	% for icell=1:length(Data)
99
100	DataOut=Data;%default
101	DataOut.CoordType='phys'; %put flag for physical coordinates
102	% The transform ACTS ONLY IF .CoordType='px'and Calib defined
103	if isfield(Data,'CoordType')&& isequal(Data.CoordType,'px')&& ~isempty(Calib)
104	if isfield(Calib,'CoordUnit')
105	DataOut.CoordUnit=Calib.CoordUnit;
106	else
107	DataOut.CoordUnit='cm'; %default
108	% elseif isfield(DataOut,'CoordUnit')
109	% DataOut=rmfield(DataOut,'CoordUnit');
110	end
111	DataOut.TimeUnit='s';
112	%transform of X,Y coordinates for vector fields
113	if isfield(Data,'ZIndex') && ~isempty(Data.ZIndex)
114	Z=Data.ZIndex;
115	else
116	Z=0;
117	end
118	if isfield(Data,'X') &&isfield(Data,'Y')&&~isempty(Data.X) && ~isempty(Data.Y)
119	[DataOut.X,DataOut.Y,DataOut.Z]=phys_XYZ(Calib,Data.X,Data.Y,Z);
120	if isfield(Data,'U')&&isfield(Data,'V')&&~isempty(Data.U) && ~isempty(Data.V)&& isfield(Data,'dt')
121	if ~isempty(Data.dt)
122	[XOut_1,YOut_1]=phys_XYZ(Calib,Data.X-Data.U/2,Data.Y-Data.V/2,Z);
123	[XOut_2,YOut_2]=phys_XYZ(Calib,Data.X+Data.U/2,Data.Y+Data.V/2,Z);
124	DataOut.U=(XOut_2-XOut_1)/Data.dt;
125	DataOut.V=(YOut_2-YOut_1)/Data.dt;
126	end
127	end
128	end
129	%transform of an image or scalar: done in phys_ima
130
131	%transform of spatial derivatives
132	if isfield(Data,'X') && ~isempty(Data.X) && isfield(Data,'DjUi') && ~isempty(Data.DjUi)...
133	&& isfield(Data,'dt')
134	if ~isempty(Data.dt)
135	% estimate the Jacobian matrix DXpx/DXphys
136	for ip=1:length(Data.X)
137	[Xp1,Yp1]=phys_XYZ(Calib,Data.X(ip)+0.5,Data.Y(ip),Z);
138	[Xm1,Ym1]=phys_XYZ(Calib,Data.X(ip)-0.5,Data.Y(ip),Z);
139	[Xp2,Yp2]=phys_XYZ(Calib,Data.X(ip),Data.Y(ip)+0.5,Z);
140	[Xm2,Ym2]=phys_XYZ(Calib,Data.X(ip),Data.Y(ip)-0.5,Z);
141	%Jacobian matrix DXpphys/DXpx
142	DjXi(1,1)=(Xp1-Xm1);
143	DjXi(2,1)=(Yp1-Ym1);
144	DjXi(1,2)=(Xp2-Xm2);
145	DjXi(2,2)=(Yp2-Ym2);
146	DjUi(:,:)=Data.DjUi(ip,:,:);
147	DjUi=(DjXiDjUi')/DjXi;% =J-1M*J , curvature effects (derivatives of J) neglected
148	DataOut.DjUi(ip,:,:)=DjUi';
149	end
150	DataOut.DjUi = DataOut.DjUi/Data.dt; % min(Data.DjUi(:,1,1))=DUDX
151	end
152	end
153	end
154
155
156	%%%%%%%%%%%%%%%%%%%%
157	function [A_out,Rangx,Rangy]=phys_Ima(A,CalibIn,ZIndex)
158	xcorner=[];
159	ycorner=[];
160	npx=[];
161	npy=[];
162	for icell=1:length(A)
163	siz=size(A{icell});
164	npx=[npx siz(2)];
165	npy=[npy siz(1)];
166	Calib=CalibIn{icell};
167	xima=[0.5 siz(2)-0.5 0.5 siz(2)-0.5];%image coordiantes of corners
168	yima=[0.5 0.5 siz(1)-0.5 siz(1)-0.5];
169	[xcorner_new,ycorner_new]=phys_XYZ(Calib,xima,yima,ZIndex);%corresponding physical coordinates
170	dx(icell)=(max(xcorner_new)-min(xcorner_new))/(siz(2)-1);
171	dy(icell)=(max(ycorner_new)-min(ycorner_new))/(siz(1)-1);
172	xcorner=[xcorner xcorner_new];
173	ycorner=[ycorner ycorner_new];
174	end
175	Rangx(1)=min(xcorner);
176	Rangx(2)=max(xcorner);
177	Rangy(2)=min(ycorner);
178	Rangy(1)=max(ycorner);
179	test_multi=(max(npx)~=min(npx)) \| (max(npy)~=min(npy));
180	npX=1+round((Rangx(2)-Rangx(1))/min(dx));% nbre of pixels in the new image (use the finest resolution min(dx) in the set of images)
181	npY=1+round((Rangy(1)-Rangy(2))/min(dy));
182	x=linspace(Rangx(1),Rangx(2),npX);
183	y=linspace(Rangy(1),Rangy(2),npY);
184	[X,Y]=meshgrid(x,y);%grid in physical coordiantes
185	vec_B=[];
186	A_out={};
187	for icell=1:length(A)
188	Calib=CalibIn{icell};
189	if (isfield(Calib,'R') && ~isequal(Calib.R(2,1),0) && ~isequal(Calib.R(1,2),0)) \|\|...
190	((isfield(Calib,'kappa1')&& ~isequal(Calib.kappa1,0))) \|\| test_multi \|\| ~isequal(Calib,CalibIn{1})
191	zphys=0; %default
192	if isfield(Calib,'SliceCoord') %.Z= index of plane
193	SliceCoord=Calib.SliceCoord(ZIndex,:);
194	zphys=SliceCoord(3); %to generalize for non-parallel planes
195	end
196	[XIMA,YIMA]=px_XYZ(CalibIn{icell},X,Y,zphys);% image coordinates for each point in the real space grid
197	XIMA=reshape(round(XIMA),1,npX*npY);%indices reorganized in 'line'
198	YIMA=reshape(round(YIMA),1,npX*npY);
199	flagin=XIMA>=1 & XIMA<=npx(icell) & YIMA >=1 & YIMA<=npy(icell);%flagin=1 inside the original image
200	testuint8=isa(A{icell},'uint8');
201	testuint16=isa(A{icell},'uint16');
202	if numel(siz)==2 %(B/W images)
203	vec_A=reshape(A{icell},1,npx(icell)*npy(icell));%put the original image in line
204	ind_in=find(flagin);
205	ind_out=find(~flagin);
206	ICOMB=((XIMA-1)*npy(icell)+(npy(icell)+1-YIMA));
207	ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
208	vec_B(ind_in)=vec_A(ICOMB);
209	vec_B(ind_out)=zeros(size(ind_out));
210	A_out{icell}=reshape(vec_B,npY,npX);%new image in real coordinates
211	elseif numel(siz)==3
212	for icolor=1:siz(3)
213	vec_A=reshape(A{icell}(:,:,icolor),1,npx*npy);%put the original image in line
214	ind_in=find(flagin);
215	ind_out=find(~flagin);
216	ICOMB=((XIMA-1)*npy+(npy+1-YIMA));
217	ICOMB=ICOMB(flagin);%index corresponding to XIMA and YIMA in the aligned original image vec_A
218	vec_B(ind_in)=vec_A(ICOMB);
219	vec_B(ind_out)=zeros(size(ind_out));
220	A_out{icell}(:,:,icolor)=reshape(vec_B,npy,npx);%new image in real coordinates
221	end
222	end
223	if testuint8
224	A_out{icell}=uint8(A_out{icell});
225	end
226	if testuint16
227	A_out{icell}=uint16(A_out{icell});
228	end
229	else%
230
231	A_out{icell}=A{icell};%no transform
232	Rangx=[0.5 npx-0.5];%image coordiantes of corners
233	Rangy=[npy-0.5 0.5];
234	[Rangx]=phys_XYZ(Calib,Rangx,[0.5 0.5],[ZIndex ZIndex]);%case of translations without rotation and quadratic deformation
235	[xx,Rangy]=phys_XYZ(Calib,[0.5 0.5],Rangy,[ZIndex ZIndex]);
236	end
237	end
238
239	%'phys_XYZ':transforms image (px) to real world (phys) coordinates using geometric calibration parameters
240	% function [Xphys,Yphys]=phys_XYZ(Calib,X,Y,Z)
241	%
242	%OUTPUT:
243	%
244	%INPUT:
245	%Z: index of plane
246	function [Xphys,Yphys,Zphys]=phys_XYZ(Calib,X,Y,Z)
247	if exist('Z','var')& isequal(Z,round(Z))& Z>0 & isfield(Calib,'SliceCoord')&length(Calib.SliceCoord)>=Z
248	Zindex=Z;
249	Zphys=Calib.SliceCoord(Zindex,3);%GENERALISER AUX CAS AVEC ANGLE
250	else
251	% if exist('Z','var')
252	% Zphys=Z;
253	% else
254	Zphys=0;
255	% end
256	end
257	if ~exist('X','var')\|\|~exist('Y','var')
258	Xphys=[];
259	Yphys=[];%default
260	return
261	end
262	Xphys=X;%default
263	Yphys=Y;
264	%image transform
265	if isfield(Calib,'R')
266	R=(Calib.R)';
267	Dx=R(5)R(7)-R(4)R(8);
268	Dy=R(1)R(8)-R(2)R(7);
269	D0=Calib.f(R(2)R(4)-R(1)*R(5));
270	Z11=R(6)R(8)-R(5)R(9);
271	Z12=R(2)R(9)-R(3)R(8);
272	Z21=R(4)R(9)-R(6)R(7);
273	Z22=R(3)R(7)-R(1)R(9);
274	Zx0=R(3)R(5)-R(2)R(6);
275	Zy0=R(1)R(6)-R(3)R(4);
276	A11=R(8)Calib.Ty-R(5)Calib.Tz+Z11*Zphys;
277	A12=R(2)Calib.Tz-R(8)Calib.Tx+Z12*Zphys;
278	A21=-R(7)Calib.Ty+R(4)Calib.Tz+Z21*Zphys;
279	A22=-R(1)Calib.Tz+R(7)Calib.Tx+Z11*Zphys;
280	X0=Calib.f(R(5)Calib.Tx-R(2)Calib.Ty+Zx0Zphys);
281	Y0=Calib.f(-R(4)Calib.Tx+R(1)Calib.Ty+Zy0Zphys);
282	%px to camera:
283	Xd=(Calib.dpx/Calib.sx)*(X-Calib.Cx); % sensor coordinates
284	Yd=Calib.dpy*(Y-Calib.Cy);
285	dist_fact=1+Calib.kappa1(Xd.Xd+Yd.*Yd); %distortion factor
286	Xu=dist_fact.*Xd;%undistorted sensor coordinates
287	Yu=dist_fact.*Yd;
288	denom=DxXu+DyYu+D0;
289	% denom2=denom.*denom;
290	Xphys=(A11.Xu+A12.Yu+X0)./denom;%world coordinates
291	Yphys=(A21.Xu+A22.Yu+Y0)./denom;
292	end
293
294	%'px_XYZ': transform phys coordinates to image coordinates (px)
295	%
296	% OUPUT:
297	% X,Y: array of coordinates in the image cooresponding to the input physical positions
298	% (origin at lower leftcorner, unit=pixel)
299
300	% INPUT:
301	% Calib: structure containing the calibration parameters (read from the ImaDoc .xml file)
302	% Xphys, Yphys: array of x,y physical coordinates
303	% [Zphys]: corresponding array of z physical coordinates (0 by default)
304
305
306
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