• Home
  • Line#
  • Scopes#
  • Navigate#
  • Raw
  • Download
1 /*
2  * Copyright (C) 2011 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 /* $Id: db_rob_image_homography.cpp,v 1.2 2011/06/17 14:03:31 mbansal Exp $ */
18 
19 #include "db_utilities.h"
20 #include "db_rob_image_homography.h"
21 #include "db_bundle.h"
22 
23 
24 
25 /*****************************************************************
26 *    Lean and mean begins here                                   *
27 *****************************************************************/
28 
29 #include "db_image_homography.h"
30 
31 #ifdef _VERBOSE_
32 #include <iostream>
33 using namespace std;
34 #endif /*VERBOSE*/
35 
db_RobImageHomography_Cost(double H[9],int point_count,double * x_i,double * xp_i,double one_over_scale2)36 inline double db_RobImageHomography_Cost(double H[9],int point_count,double *x_i,double *xp_i,double one_over_scale2)
37 {
38     int c;
39     double back,acc,*x_i_temp,*xp_i_temp;
40 
41     for(back=0.0,c=0;c<point_count;)
42     {
43         /*Take log of product of ten reprojection
44         errors to reduce nr of expensive log operations*/
45         if(c+9<point_count)
46         {
47             x_i_temp=x_i+(c<<1);
48             xp_i_temp=xp_i+(c<<1);
49 
50             acc=db_ExpCauchyInhomogenousHomographyError(xp_i_temp,H,x_i_temp,one_over_scale2);
51             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+2,H,x_i_temp+2,one_over_scale2);
52             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+4,H,x_i_temp+4,one_over_scale2);
53             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+6,H,x_i_temp+6,one_over_scale2);
54             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+8,H,x_i_temp+8,one_over_scale2);
55             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+10,H,x_i_temp+10,one_over_scale2);
56             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+12,H,x_i_temp+12,one_over_scale2);
57             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+14,H,x_i_temp+14,one_over_scale2);
58             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+16,H,x_i_temp+16,one_over_scale2);
59             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+18,H,x_i_temp+18,one_over_scale2);
60             c+=10;
61         }
62         else
63         {
64             for(acc=1.0;c<point_count;c++)
65             {
66                 acc*=db_ExpCauchyInhomogenousHomographyError(xp_i+(c<<1),H,x_i+(c<<1),one_over_scale2);
67             }
68         }
69         back+=log(acc);
70     }
71     return(back);
72 }
73 
db_RobImageHomography_Statistics(double H[9],int point_count,double * x_i,double * xp_i,double one_over_scale2,db_Statistics * stat,double thresh=DB_OUTLIER_THRESHOLD)74 inline double db_RobImageHomography_Statistics(double H[9],int point_count,double *x_i,double *xp_i,double one_over_scale2,db_Statistics *stat,double thresh=DB_OUTLIER_THRESHOLD)
75 {
76     int c,i;
77     double t2,frac;
78 
79     t2=thresh*thresh;
80     for(i=0,c=0;c<point_count;c++)
81     {
82         i+=(db_SquaredInhomogenousHomographyError(xp_i+(c<<1),H,x_i+(c<<1))*one_over_scale2<=t2)?1:0;
83     }
84     frac=((double)i)/((double)(db_maxi(point_count,1)));
85 
86 #ifdef _VERBOSE_
87     std::cout << "Inlier Percentage RobImageHomography: " << frac*100.0 << "% out of " << point_count << " constraints" << std::endl;
88 #endif /*_VERBOSE_*/
89 
90     if(stat)
91     {
92         stat->nr_points=point_count;
93         stat->one_over_scale2=one_over_scale2;
94         stat->nr_inliers=i;
95         stat->inlier_fraction=frac;
96 
97         stat->cost=db_RobImageHomography_Cost(H,point_count,x_i,xp_i,one_over_scale2);
98         stat->model_dimension=0;
99         /*stat->nr_parameters=;*/
100 
101         stat->lambda1=log(4.0);
102         stat->lambda2=log(4.0*((double)db_maxi(1,stat->nr_points)));
103         stat->lambda3=10.0;
104         stat->gric=stat->cost+stat->lambda1*stat->model_dimension*((double)stat->nr_points)+stat->lambda2*((double)stat->nr_parameters);
105         stat->inlier_evidence=((double)stat->nr_inliers)-stat->lambda3*((double)stat->nr_parameters);
106     }
107 
108     return(frac);
109 }
110 
111 /*Compute min_Jtf and upper right of JtJ. Return cost.*/
db_RobImageHomography_Jacobians(double JtJ[81],double min_Jtf[9],double H[9],int point_count,double * x_i,double * xp_i,double one_over_scale2)112 inline double db_RobImageHomography_Jacobians(double JtJ[81],double min_Jtf[9],double H[9],int point_count,double *x_i,double *xp_i,double one_over_scale2)
113 {
114     double back,Jf_dx[18],f[2],temp,temp2;
115     int i;
116 
117     db_Zero(JtJ,81);
118     db_Zero(min_Jtf,9);
119     for(back=0.0,i=0;i<point_count;i++)
120     {
121         /*Compute reprojection error vector and its Jacobian
122         for this point*/
123         db_DerivativeCauchyInhomHomographyReprojection(Jf_dx,f,xp_i+(i<<1),H,x_i+(i<<1),one_over_scale2);
124         /*Perform
125         min_Jtf-=Jf_dx*f[0] and
126         min_Jtf-=(Jf_dx+9)*f[1] to accumulate -Jt%f*/
127         db_RowOperation9(min_Jtf,Jf_dx,f[0]);
128         db_RowOperation9(min_Jtf,Jf_dx+9,f[1]);
129         /*Accumulate upper right of JtJ with outer product*/
130         temp=Jf_dx[0]; temp2=Jf_dx[9];
131         JtJ[0]+=temp*Jf_dx[0]+temp2*Jf_dx[9];
132         JtJ[1]+=temp*Jf_dx[1]+temp2*Jf_dx[10];
133         JtJ[2]+=temp*Jf_dx[2]+temp2*Jf_dx[11];
134         JtJ[3]+=temp*Jf_dx[3]+temp2*Jf_dx[12];
135         JtJ[4]+=temp*Jf_dx[4]+temp2*Jf_dx[13];
136         JtJ[5]+=temp*Jf_dx[5]+temp2*Jf_dx[14];
137         JtJ[6]+=temp*Jf_dx[6]+temp2*Jf_dx[15];
138         JtJ[7]+=temp*Jf_dx[7]+temp2*Jf_dx[16];
139         JtJ[8]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
140         temp=Jf_dx[1]; temp2=Jf_dx[10];
141         JtJ[10]+=temp*Jf_dx[1]+temp2*Jf_dx[10];
142         JtJ[11]+=temp*Jf_dx[2]+temp2*Jf_dx[11];
143         JtJ[12]+=temp*Jf_dx[3]+temp2*Jf_dx[12];
144         JtJ[13]+=temp*Jf_dx[4]+temp2*Jf_dx[13];
145         JtJ[14]+=temp*Jf_dx[5]+temp2*Jf_dx[14];
146         JtJ[15]+=temp*Jf_dx[6]+temp2*Jf_dx[15];
147         JtJ[16]+=temp*Jf_dx[7]+temp2*Jf_dx[16];
148         JtJ[17]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
149         temp=Jf_dx[2]; temp2=Jf_dx[11];
150         JtJ[20]+=temp*Jf_dx[2]+temp2*Jf_dx[11];
151         JtJ[21]+=temp*Jf_dx[3]+temp2*Jf_dx[12];
152         JtJ[22]+=temp*Jf_dx[4]+temp2*Jf_dx[13];
153         JtJ[23]+=temp*Jf_dx[5]+temp2*Jf_dx[14];
154         JtJ[24]+=temp*Jf_dx[6]+temp2*Jf_dx[15];
155         JtJ[25]+=temp*Jf_dx[7]+temp2*Jf_dx[16];
156         JtJ[26]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
157         temp=Jf_dx[3]; temp2=Jf_dx[12];
158         JtJ[30]+=temp*Jf_dx[3]+temp2*Jf_dx[12];
159         JtJ[31]+=temp*Jf_dx[4]+temp2*Jf_dx[13];
160         JtJ[32]+=temp*Jf_dx[5]+temp2*Jf_dx[14];
161         JtJ[33]+=temp*Jf_dx[6]+temp2*Jf_dx[15];
162         JtJ[34]+=temp*Jf_dx[7]+temp2*Jf_dx[16];
163         JtJ[35]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
164         temp=Jf_dx[4]; temp2=Jf_dx[13];
165         JtJ[40]+=temp*Jf_dx[4]+temp2*Jf_dx[13];
166         JtJ[41]+=temp*Jf_dx[5]+temp2*Jf_dx[14];
167         JtJ[42]+=temp*Jf_dx[6]+temp2*Jf_dx[15];
168         JtJ[43]+=temp*Jf_dx[7]+temp2*Jf_dx[16];
169         JtJ[44]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
170         temp=Jf_dx[5]; temp2=Jf_dx[14];
171         JtJ[50]+=temp*Jf_dx[5]+temp2*Jf_dx[14];
172         JtJ[51]+=temp*Jf_dx[6]+temp2*Jf_dx[15];
173         JtJ[52]+=temp*Jf_dx[7]+temp2*Jf_dx[16];
174         JtJ[53]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
175         temp=Jf_dx[6]; temp2=Jf_dx[15];
176         JtJ[60]+=temp*Jf_dx[6]+temp2*Jf_dx[15];
177         JtJ[61]+=temp*Jf_dx[7]+temp2*Jf_dx[16];
178         JtJ[62]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
179         temp=Jf_dx[7]; temp2=Jf_dx[16];
180         JtJ[70]+=temp*Jf_dx[7]+temp2*Jf_dx[16];
181         JtJ[71]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
182         temp=Jf_dx[8]; temp2=Jf_dx[17];
183         JtJ[80]+=temp*Jf_dx[8]+temp2*Jf_dx[17];
184 
185         /*Add square-sum to cost*/
186         back+=db_sqr(f[0])+db_sqr(f[1]);
187     }
188 
189     return(back);
190 }
191 
192 /*Compute min_Jtf and upper right of JtJ. Return cost*/
db_RobCamRotation_Jacobians(double JtJ[9],double min_Jtf[3],double H[9],int point_count,double * x_i,double * xp_i,double one_over_scale2)193 inline double db_RobCamRotation_Jacobians(double JtJ[9],double min_Jtf[3],double H[9],int point_count,double *x_i,double *xp_i,double one_over_scale2)
194 {
195     double back,Jf_dx[6],f[2];
196     int i,j;
197 
198     db_Zero(JtJ,9);
199     db_Zero(min_Jtf,3);
200     for(back=0.0,i=0;i<point_count;i++)
201     {
202         /*Compute reprojection error vector and its Jacobian
203         for this point*/
204         j=(i<<1);
205         db_DerivativeCauchyInhomRotationReprojection(Jf_dx,f,xp_i+j,H,x_i+j,one_over_scale2);
206         /*Perform
207         min_Jtf-=Jf_dx*f[0] and
208         min_Jtf-=(Jf_dx+3)*f[1] to accumulate -Jt%f*/
209         db_RowOperation3(min_Jtf,Jf_dx,f[0]);
210         db_RowOperation3(min_Jtf,Jf_dx+3,f[1]);
211         /*Accumulate upper right of JtJ with outer product*/
212         JtJ[0]+=Jf_dx[0]*Jf_dx[0]+Jf_dx[3]*Jf_dx[3];
213         JtJ[1]+=Jf_dx[0]*Jf_dx[1]+Jf_dx[3]*Jf_dx[4];
214         JtJ[2]+=Jf_dx[0]*Jf_dx[2]+Jf_dx[3]*Jf_dx[5];
215         JtJ[4]+=Jf_dx[1]*Jf_dx[1]+Jf_dx[4]*Jf_dx[4];
216         JtJ[5]+=Jf_dx[1]*Jf_dx[2]+Jf_dx[4]*Jf_dx[5];
217         JtJ[8]+=Jf_dx[2]*Jf_dx[2]+Jf_dx[5]*Jf_dx[5];
218 
219         /*Add square-sum to cost*/
220         back+=db_sqr(f[0])+db_sqr(f[1]);
221     }
222 
223     return(back);
224 }
225 
db_RobCamRotation_Polish(double H[9],int point_count,double * x_i,double * xp_i,double one_over_scale2,int max_iterations,double improvement_requirement)226 void db_RobCamRotation_Polish(double H[9],int point_count,double *x_i,double *xp_i,double one_over_scale2,
227                                int max_iterations,double improvement_requirement)
228 {
229     int i,update,stop;
230     double lambda,cost,current_cost;
231     double JtJ[9],min_Jtf[3],dx[3],H_p_dx[9];
232 
233     lambda=0.001;
234     for(update=1,stop=0,i=0;(stop<2) && (i<max_iterations);i++)
235     {
236         /*if first time since improvement, compute Jacobian and residual*/
237         if(update)
238         {
239             current_cost=db_RobCamRotation_Jacobians(JtJ,min_Jtf,H,point_count,x_i,xp_i,one_over_scale2);
240             update=0;
241         }
242 
243 #ifdef _VERBOSE_
244         /*std::cout << "Cost:" << current_cost << " ";*/
245 #endif /*_VERBOSE_*/
246 
247         /*Come up with a hypothesis dx
248         based on the current lambda*/
249         db_Compute_dx_3x3(dx,JtJ,min_Jtf,lambda);
250 
251         /*Compute Cost(x+dx)*/
252         db_UpdateRotation(H_p_dx,H,dx);
253         cost=db_RobImageHomography_Cost(H_p_dx,point_count,x_i,xp_i,one_over_scale2);
254 
255         /*Is there an improvement?*/
256         if(cost<current_cost)
257         {
258             /*improvement*/
259             if(current_cost-cost<current_cost*improvement_requirement) stop++;
260             else stop=0;
261             lambda*=0.1;
262             /*Move to the hypothesised position x+dx*/
263             current_cost=cost;
264             db_Copy9(H,H_p_dx);
265             db_OrthonormalizeRotation(H);
266             update=1;
267 
268 #ifdef _VERBOSE_
269         std::cout << "Step" << i << "Imp,Lambda=" << lambda << "Cost:" << current_cost << std::endl;
270 #endif /*_VERBOSE_*/
271         }
272         else
273         {
274             /*no improvement*/
275             lambda*=10.0;
276             stop=0;
277         }
278     }
279 }
280 
db_RobImageHomographyFetchJacobian(double ** JtJ_ref,double * min_Jtf,double ** JtJ_temp_ref,double * min_Jtf_temp,int n,int * fetch_vector)281 inline void db_RobImageHomographyFetchJacobian(double **JtJ_ref,double *min_Jtf,double **JtJ_temp_ref,double *min_Jtf_temp,int n,int *fetch_vector)
282 {
283     int i,j,t;
284     double *t1,*t2;
285 
286     for(i=0;i<n;i++)
287     {
288         t=fetch_vector[i];
289         min_Jtf[i]=min_Jtf_temp[t];
290         t1=JtJ_ref[i];
291         t2=JtJ_temp_ref[t];
292         for(j=i;j<n;j++)
293         {
294             t1[j]=t2[fetch_vector[j]];
295         }
296     }
297 }
298 
db_RobImageHomographyMultiplyJacobian(double ** JtJ_ref,double * min_Jtf,double ** JtJ_temp_ref,double * min_Jtf_temp,double ** JE_dx_ref,int n)299 inline void db_RobImageHomographyMultiplyJacobian(double **JtJ_ref,double *min_Jtf,double **JtJ_temp_ref,double *min_Jtf_temp,double **JE_dx_ref,int n)
300 {
301     double JtJ_JE[72],*JtJ_JE_ref[9];
302 
303     db_SetupMatrixRefs(JtJ_JE_ref,9,8,JtJ_JE);
304 
305     db_SymmetricExtendUpperToLower(JtJ_temp_ref,9,9);
306     db_MultiplyMatricesAB(JtJ_JE_ref,JtJ_temp_ref,JE_dx_ref,9,9,n);
307     db_UpperMultiplyMatricesAtB(JtJ_ref,JE_dx_ref,JtJ_JE_ref,n,9,n);
308     db_MultiplyMatrixVectorAtb(min_Jtf,JE_dx_ref,min_Jtf_temp,n,9);
309 }
310 
db_RobImageHomographyJH_Js(double ** JE_dx_ref,int j,double H[9])311 inline void db_RobImageHomographyJH_Js(double **JE_dx_ref,int j,double H[9])
312 {
313     /*Update of upper 2x2 is multiplication by
314     [s 0][ cos(theta) sin(theta)]
315     [0 s][-sin(theta) cos(theta)]*/
316     JE_dx_ref[0][j]=H[0];
317     JE_dx_ref[1][j]=H[1];
318     JE_dx_ref[2][j]=0;
319     JE_dx_ref[3][j]=H[2];
320     JE_dx_ref[4][j]=H[3];
321     JE_dx_ref[5][j]=0;
322     JE_dx_ref[6][j]=0;
323     JE_dx_ref[7][j]=0;
324     JE_dx_ref[8][j]=0;
325 }
326 
db_RobImageHomographyJH_JR(double ** JE_dx_ref,int j,double H[9])327 inline void db_RobImageHomographyJH_JR(double **JE_dx_ref,int j,double H[9])
328 {
329     /*Update of upper 2x2 is multiplication by
330     [s 0][ cos(theta) sin(theta)]
331     [0 s][-sin(theta) cos(theta)]*/
332     JE_dx_ref[0][j]=  H[3];
333     JE_dx_ref[1][j]=  H[4];
334     JE_dx_ref[2][j]=0;
335     JE_dx_ref[3][j]= -H[0];
336     JE_dx_ref[4][j]= -H[1];
337     JE_dx_ref[5][j]=0;
338     JE_dx_ref[6][j]=0;
339     JE_dx_ref[7][j]=0;
340     JE_dx_ref[8][j]=0;
341 }
342 
db_RobImageHomographyJH_Jt(double ** JE_dx_ref,int j,int k,double H[9])343 inline void db_RobImageHomographyJH_Jt(double **JE_dx_ref,int j,int k,double H[9])
344 {
345     JE_dx_ref[0][j]=0;
346     JE_dx_ref[1][j]=0;
347     JE_dx_ref[2][j]=1.0;
348     JE_dx_ref[3][j]=0;
349     JE_dx_ref[4][j]=0;
350     JE_dx_ref[5][j]=0;
351     JE_dx_ref[6][j]=0;
352     JE_dx_ref[7][j]=0;
353     JE_dx_ref[8][j]=0;
354 
355     JE_dx_ref[0][k]=0;
356     JE_dx_ref[1][k]=0;
357     JE_dx_ref[2][k]=0;
358     JE_dx_ref[3][k]=0;
359     JE_dx_ref[4][k]=0;
360     JE_dx_ref[5][k]=1.0;
361     JE_dx_ref[6][k]=0;
362     JE_dx_ref[7][k]=0;
363     JE_dx_ref[8][k]=0;
364 }
365 
db_RobImageHomographyJH_dRotFocal(double ** JE_dx_ref,int j,int k,int l,int m,double H[9])366 inline void db_RobImageHomographyJH_dRotFocal(double **JE_dx_ref,int j,int k,int l,int m,double H[9])
367 {
368     double f,fi,fi2;
369     double R[9],J[9];
370 
371     /*Updated matrix is diag(f+df,f+df)*dR*R*diag(1/(f+df),1/(f+df),1)*/
372     f=db_FocalAndRotFromCamRotFocalHomography(R,H);
373     fi=db_SafeReciprocal(f);
374     fi2=db_sqr(fi);
375     db_JacobianOfRotatedPointStride(J,R,3);
376     JE_dx_ref[0][j]=   J[0];
377     JE_dx_ref[1][j]=   J[1];
378     JE_dx_ref[2][j]=f* J[2];
379     JE_dx_ref[3][j]=   J[3];
380     JE_dx_ref[4][j]=   J[4];
381     JE_dx_ref[5][j]=f* J[5];
382     JE_dx_ref[6][j]=fi*J[6];
383     JE_dx_ref[7][j]=fi*J[7];
384     JE_dx_ref[8][j]=   J[8];
385     db_JacobianOfRotatedPointStride(J,R+1,3);
386     JE_dx_ref[0][k]=   J[0];
387     JE_dx_ref[1][k]=   J[1];
388     JE_dx_ref[2][k]=f* J[2];
389     JE_dx_ref[3][k]=   J[3];
390     JE_dx_ref[4][k]=   J[4];
391     JE_dx_ref[5][k]=f* J[5];
392     JE_dx_ref[6][k]=fi*J[6];
393     JE_dx_ref[7][k]=fi*J[7];
394     JE_dx_ref[8][k]=   J[8];
395     db_JacobianOfRotatedPointStride(J,R+2,3);
396     JE_dx_ref[0][l]=   J[0];
397     JE_dx_ref[1][l]=   J[1];
398     JE_dx_ref[2][l]=f* J[2];
399     JE_dx_ref[3][l]=   J[3];
400     JE_dx_ref[4][l]=   J[4];
401     JE_dx_ref[5][l]=f* J[5];
402     JE_dx_ref[6][l]=fi*J[6];
403     JE_dx_ref[7][l]=fi*J[7];
404     JE_dx_ref[8][l]=   J[8];
405 
406     JE_dx_ref[0][m]=0;
407     JE_dx_ref[1][m]=0;
408     JE_dx_ref[2][m]=H[2];
409     JE_dx_ref[3][m]=0;
410     JE_dx_ref[4][m]=0;
411     JE_dx_ref[5][m]=H[5];
412     JE_dx_ref[6][m]= -fi2*H[6];
413     JE_dx_ref[7][m]= -fi2*H[7];
414     JE_dx_ref[8][m]=0;
415 }
416 
db_RobImageHomography_Jacobians_Generic(double * JtJ_ref[8],double min_Jtf[8],int * num_param,int * frozen_coord,double H[9],int point_count,double * x_i,double * xp_i,int homography_type,double one_over_scale2)417 inline double db_RobImageHomography_Jacobians_Generic(double *JtJ_ref[8],double min_Jtf[8],int *num_param,int *frozen_coord,double H[9],int point_count,double *x_i,double *xp_i,int homography_type,double one_over_scale2)
418 {
419     double back;
420     int i,j,fetch_vector[8],n;
421     double JtJ_temp[81],min_Jtf_temp[9],JE_dx[72];
422     double *JE_dx_ref[9],*JtJ_temp_ref[9];
423 
424     /*Compute cost and JtJ,min_Jtf with respect to H*/
425     back=db_RobImageHomography_Jacobians(JtJ_temp,min_Jtf_temp,H,point_count,x_i,xp_i,one_over_scale2);
426 
427     /*Compute JtJ,min_Jtf with respect to the right parameters
428     The formulas are
429     JtJ=transpose(JE_dx)*JtJ*JE_dx and
430     min_Jtf=transpose(JE_dx)*min_Jtf,
431     where the 9xN matrix JE_dx is the Jacobian of H with respect
432     to the update*/
433     db_SetupMatrixRefs(JtJ_temp_ref,9,9,JtJ_temp);
434     db_SetupMatrixRefs(JE_dx_ref,9,8,JE_dx);
435     switch(homography_type)
436     {
437         case DB_HOMOGRAPHY_TYPE_SIMILARITY:
438         case DB_HOMOGRAPHY_TYPE_SIMILARITY_U:
439             n=4;
440             db_RobImageHomographyJH_Js(JE_dx_ref,0,H);
441             db_RobImageHomographyJH_JR(JE_dx_ref,1,H);
442             db_RobImageHomographyJH_Jt(JE_dx_ref,2,3,H);
443             db_RobImageHomographyMultiplyJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,JE_dx_ref,n);
444             break;
445         case DB_HOMOGRAPHY_TYPE_ROTATION:
446         case DB_HOMOGRAPHY_TYPE_ROTATION_U:
447             n=1;
448             db_RobImageHomographyJH_JR(JE_dx_ref,0,H);
449             db_RobImageHomographyMultiplyJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,JE_dx_ref,n);
450             break;
451         case DB_HOMOGRAPHY_TYPE_SCALING:
452             n=1;
453             db_RobImageHomographyJH_Js(JE_dx_ref,0,H);
454             db_RobImageHomographyMultiplyJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,JE_dx_ref,n);
455             break;
456         case DB_HOMOGRAPHY_TYPE_S_T:
457             n=3;
458             db_RobImageHomographyJH_Js(JE_dx_ref,0,H);
459             db_RobImageHomographyJH_Jt(JE_dx_ref,1,2,H);
460             db_RobImageHomographyMultiplyJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,JE_dx_ref,n);
461             break;
462         case DB_HOMOGRAPHY_TYPE_R_T:
463             n=3;
464             db_RobImageHomographyJH_JR(JE_dx_ref,0,H);
465             db_RobImageHomographyJH_Jt(JE_dx_ref,1,2,H);
466             db_RobImageHomographyMultiplyJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,JE_dx_ref,n);
467             break;
468         case DB_HOMOGRAPHY_TYPE_R_S:
469             n=2;
470             db_RobImageHomographyJH_Js(JE_dx_ref,0,H);
471             db_RobImageHomographyJH_JR(JE_dx_ref,1,H);
472             db_RobImageHomographyMultiplyJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,JE_dx_ref,n);
473             break;
474 
475         case DB_HOMOGRAPHY_TYPE_TRANSLATION:
476             n=2;
477             fetch_vector[0]=2;
478             fetch_vector[1]=5;
479             db_RobImageHomographyFetchJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,n,fetch_vector);
480             break;
481         case DB_HOMOGRAPHY_TYPE_AFFINE:
482             n=6;
483             fetch_vector[0]=0;
484             fetch_vector[1]=1;
485             fetch_vector[2]=2;
486             fetch_vector[3]=3;
487             fetch_vector[4]=4;
488             fetch_vector[5]=5;
489             db_RobImageHomographyFetchJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,n,fetch_vector);
490             break;
491         case DB_HOMOGRAPHY_TYPE_PROJECTIVE:
492             n=8;
493             *frozen_coord=db_MaxAbsIndex9(H);
494             for(j=0,i=0;i<9;i++) if(i!=(*frozen_coord))
495             {
496                 fetch_vector[j]=i;
497                 j++;
498             }
499             db_RobImageHomographyFetchJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,n,fetch_vector);
500             break;
501         case DB_HOMOGRAPHY_TYPE_CAMROTATION_F:
502         case DB_HOMOGRAPHY_TYPE_CAMROTATION_F_UD:
503             n=4;
504             db_RobImageHomographyJH_dRotFocal(JE_dx_ref,0,1,2,3,H);
505             db_RobImageHomographyMultiplyJacobian(JtJ_ref,min_Jtf,JtJ_temp_ref,min_Jtf_temp,JE_dx_ref,n);
506             break;
507     }
508     *num_param=n;
509 
510     return(back);
511 }
512 
db_ImageHomographyUpdateGeneric(double H_p_dx[9],double H[9],double * dx,int homography_type,int frozen_coord)513 inline void db_ImageHomographyUpdateGeneric(double H_p_dx[9],double H[9],double *dx,int homography_type,int frozen_coord)
514 {
515     switch(homography_type)
516     {
517         case DB_HOMOGRAPHY_TYPE_SIMILARITY:
518         case DB_HOMOGRAPHY_TYPE_SIMILARITY_U:
519             db_Copy9(H_p_dx,H);
520             db_MultiplyScaleOntoImageHomography(H,1.0+dx[0]);
521             db_MultiplyRotationOntoImageHomography(H,dx[1]);
522             H_p_dx[2]+=dx[2];
523             H_p_dx[5]+=dx[3];
524             break;
525         case DB_HOMOGRAPHY_TYPE_ROTATION:
526         case DB_HOMOGRAPHY_TYPE_ROTATION_U:
527             db_MultiplyRotationOntoImageHomography(H,dx[0]);
528             break;
529         case DB_HOMOGRAPHY_TYPE_SCALING:
530             db_MultiplyScaleOntoImageHomography(H,1.0+dx[0]);
531             break;
532         case DB_HOMOGRAPHY_TYPE_S_T:
533             db_Copy9(H_p_dx,H);
534             db_MultiplyScaleOntoImageHomography(H,1.0+dx[0]);
535             H_p_dx[2]+=dx[1];
536             H_p_dx[5]+=dx[2];
537             break;
538         case DB_HOMOGRAPHY_TYPE_R_T:
539             db_Copy9(H_p_dx,H);
540             db_MultiplyRotationOntoImageHomography(H,dx[0]);
541             H_p_dx[2]+=dx[1];
542             H_p_dx[5]+=dx[2];
543             break;
544         case DB_HOMOGRAPHY_TYPE_R_S:
545             db_Copy9(H_p_dx,H);
546             db_MultiplyScaleOntoImageHomography(H,1.0+dx[0]);
547             db_MultiplyRotationOntoImageHomography(H,dx[1]);
548             break;
549         case DB_HOMOGRAPHY_TYPE_TRANSLATION:
550             db_Copy9(H_p_dx,H);
551             H_p_dx[2]+=dx[0];
552             H_p_dx[5]+=dx[1];
553             break;
554         case DB_HOMOGRAPHY_TYPE_AFFINE:
555             db_UpdateImageHomographyAffine(H_p_dx,H,dx);
556             break;
557         case DB_HOMOGRAPHY_TYPE_PROJECTIVE:
558             db_UpdateImageHomographyProjective(H_p_dx,H,dx,frozen_coord);
559             break;
560         case DB_HOMOGRAPHY_TYPE_CAMROTATION_F:
561         case DB_HOMOGRAPHY_TYPE_CAMROTATION_F_UD:
562             db_UpdateRotFocalHomography(H_p_dx,H,dx);
563             break;
564     }
565 }
566 
db_RobCamRotation_Polish_Generic(double H[9],int point_count,int homography_type,double * x_i,double * xp_i,double one_over_scale2,int max_iterations,double improvement_requirement)567 void db_RobCamRotation_Polish_Generic(double H[9],int point_count,int homography_type,double *x_i,double *xp_i,double one_over_scale2,
568                                int max_iterations,double improvement_requirement)
569 {
570     int i,update,stop,n;
571     int frozen_coord = 0;
572     double lambda,cost,current_cost;
573     double JtJ[72],min_Jtf[9],dx[8],H_p_dx[9];
574     double *JtJ_ref[9],d[8];
575 
576     lambda=0.001;
577     for(update=1,stop=0,i=0;(stop<2) && (i<max_iterations);i++)
578     {
579         /*if first time since improvement, compute Jacobian and residual*/
580         if(update)
581         {
582             db_SetupMatrixRefs(JtJ_ref,9,8,JtJ);
583             current_cost=db_RobImageHomography_Jacobians_Generic(JtJ_ref,min_Jtf,&n,&frozen_coord,H,point_count,x_i,xp_i,homography_type,one_over_scale2);
584             update=0;
585         }
586 
587 #ifdef _VERBOSE_
588         /*std::cout << "Cost:" << current_cost << " ";*/
589 #endif /*_VERBOSE_*/
590 
591         /*Come up with a hypothesis dx
592         based on the current lambda*/
593         db_Compute_dx(dx,JtJ_ref,min_Jtf,lambda,d,n);
594 
595         /*Compute Cost(x+dx)*/
596         db_ImageHomographyUpdateGeneric(H_p_dx,H,dx,homography_type,frozen_coord);
597         cost=db_RobImageHomography_Cost(H_p_dx,point_count,x_i,xp_i,one_over_scale2);
598 
599         /*Is there an improvement?*/
600         if(cost<current_cost)
601         {
602             /*improvement*/
603             if(current_cost-cost<current_cost*improvement_requirement) stop++;
604             else stop=0;
605             lambda*=0.1;
606             /*Move to the hypothesised position x+dx*/
607             current_cost=cost;
608             db_Copy9(H,H_p_dx);
609             update=1;
610 
611 #ifdef _VERBOSE_
612         std::cout << "Step" << i << "Imp,Lambda=" << lambda << "Cost:" << current_cost << std::endl;
613 #endif /*_VERBOSE_*/
614         }
615         else
616         {
617             /*no improvement*/
618             lambda*=10.0;
619             stop=0;
620         }
621     }
622 }
db_RobImageHomography(double H[9],double * im,double * im_p,int nr_points,double K[9],double Kp[9],double * temp_d,int * temp_i,int homography_type,db_Statistics * stat,int max_iterations,int max_points,double scale,int nr_samples,int chunk_size,int outlierremoveflagE,double * wp,double * im_r,double * im_raw,double * im_raw_p,int * finalNumE)623 void db_RobImageHomography(
624                               /*Best homography*/
625                               double H[9],
626                               /*2DPoint to 2DPoint constraints
627                               Points are assumed to be given in
628                               homogenous coordinates*/
629                               double *im, double *im_p,
630                               /*Nr of points in total*/
631                               int nr_points,
632                               /*Calibration matrices
633                               used to normalize the points*/
634                               double K[9],
635                               double Kp[9],
636                               /*Pre-allocated space temp_d
637                               should point to at least
638                               12*nr_samples+10*nr_points
639                               allocated positions*/
640                               double *temp_d,
641                               /*Pre-allocated space temp_i
642                               should point to at least
643                               max(nr_samples,nr_points)
644                               allocated positions*/
645                               int *temp_i,
646                               int homography_type,
647                               db_Statistics *stat,
648                               int max_iterations,
649                               int max_points,
650                               double scale,
651                               int nr_samples,
652                               int chunk_size,
653                               /////////////////////////////////////////////
654                               // regular use: set outlierremoveflagE =0;
655                               // flag for the outlier removal
656                               int outlierremoveflagE,
657                               // if flag is 1, then the following variables
658                               // need the input
659                               //////////////////////////////////////
660                               // 3D coordinates
661                               double *wp,
662                               // its corresponding stereo pair's points
663                               double *im_r,
664                               // raw image coordinates
665                               double *im_raw, double *im_raw_p,
666                               // final matches
667                               int *finalNumE)
668 {
669     /*Random seed*/
670     int r_seed;
671 
672     int point_count_new;
673     /*Counters*/
674     int i,j,c,point_count,hyp_count;
675     int last_hyp,new_last_hyp,last_corr;
676     int pos,point_pos,last_point;
677     /*Accumulator*/
678     double acc;
679     /*Hypothesis pointer*/
680     double *hyp_point;
681     /*Random sample*/
682     int s[4];
683     /*Pivot for hypothesis pruning*/
684     double pivot;
685     /*Best hypothesis position*/
686     int best_pos;
687     /*Best score*/
688     double lowest_cost;
689     /*One over the squared scale of
690     Cauchy distribution*/
691     double one_over_scale2;
692     /*temporary pointers*/
693     double *x_i_temp,*xp_i_temp;
694     /*Temporary space for inverse calibration matrices*/
695     double K_inv[9];
696     double Kp_inv[9];
697     /*Temporary space for homography*/
698     double H_temp[9],H_temp2[9];
699     /*Pointers to homogenous coordinates*/
700     double *x_h_point,*xp_h_point;
701     /*Array of pointers to inhomogenous coordinates*/
702     double *X[3],*Xp[3];
703     /*Similarity parameters*/
704     int orientation_preserving,allow_scaling,allow_rotation,allow_translation,sample_size;
705 
706     /*Homogenous coordinates of image points in first image*/
707     double *x_h;
708     /*Homogenous coordinates of image points in second image*/
709     double *xp_h;
710     /*Inhomogenous coordinates of image points in first image*/
711     double *x_i;
712     /*Inhomogenous coordinates of image points in second image*/
713     double *xp_i;
714     /*Homography hypotheses*/
715     double *hyp_H_array;
716     /*Cost array*/
717     double *hyp_cost_array;
718     /*Permutation of the hypotheses*/
719     int *hyp_perm;
720     /*Sample of the points*/
721     int *point_perm;
722     /*Temporary space for quick-select
723     2*nr_samples*/
724     double *temp_select;
725 
726     /*Get inverse calibration matrices*/
727     db_InvertCalibrationMatrix(K_inv,K);
728     db_InvertCalibrationMatrix(Kp_inv,Kp);
729     /*Compute scale coefficient*/
730     one_over_scale2=1.0/(scale*scale);
731     /*Initialize random seed*/
732     r_seed=12345;
733     /*Set pointers to pre-allocated space*/
734     hyp_cost_array=temp_d;
735     hyp_H_array=temp_d+nr_samples;
736     temp_select=temp_d+10*nr_samples;
737     x_h=temp_d+12*nr_samples;
738     xp_h=temp_d+12*nr_samples+3*nr_points;
739     x_i=temp_d+12*nr_samples+6*nr_points;
740     xp_i=temp_d+12*nr_samples+8*nr_points;
741     hyp_perm=temp_i;
742     point_perm=temp_i;
743 
744     /*Prepare a randomly permuted subset of size
745     point_count from the input points*/
746 
747     point_count=db_mini(nr_points,(int)(chunk_size*log((double)nr_samples)/DB_LN2));
748 
749     point_count_new = point_count;
750 
751     for(i=0;i<nr_points;i++) point_perm[i]=i;
752 
753     for(last_point=nr_points-1,i=0;i<point_count;i++,last_point--)
754     {
755         pos=db_RandomInt(r_seed,last_point);
756         point_pos=point_perm[pos];
757         point_perm[pos]=point_perm[last_point];
758 
759         /*Normalize image points with calibration
760         matrices and move them to x_h and xp_h*/
761         c=3*point_pos;
762         j=3*i;
763         x_h_point=x_h+j;
764         xp_h_point=xp_h+j;
765         db_Multiply3x3_3x1(x_h_point,K_inv,im+c);
766         db_Multiply3x3_3x1(xp_h_point,Kp_inv,im_p+c);
767 
768         db_HomogenousNormalize3(x_h_point);
769         db_HomogenousNormalize3(xp_h_point);
770 
771         /*Dehomogenize image points and move them
772         to x_i and xp_i*/
773         c=(i<<1);
774         db_DeHomogenizeImagePoint(x_i+c,x_h_point); // 2-dimension
775         db_DeHomogenizeImagePoint(xp_i+c,xp_h_point); //2-dimension
776     }
777 
778 
779     /*Generate Hypotheses*/
780     hyp_count=0;
781     switch(homography_type)
782     {
783     case DB_HOMOGRAPHY_TYPE_SIMILARITY:
784     case DB_HOMOGRAPHY_TYPE_SIMILARITY_U:
785     case DB_HOMOGRAPHY_TYPE_TRANSLATION:
786     case DB_HOMOGRAPHY_TYPE_ROTATION:
787     case DB_HOMOGRAPHY_TYPE_ROTATION_U:
788     case DB_HOMOGRAPHY_TYPE_SCALING:
789     case DB_HOMOGRAPHY_TYPE_S_T:
790     case DB_HOMOGRAPHY_TYPE_R_T:
791     case DB_HOMOGRAPHY_TYPE_R_S:
792 
793         switch(homography_type)
794         {
795         case DB_HOMOGRAPHY_TYPE_SIMILARITY:
796             orientation_preserving=1;
797             allow_scaling=1;
798             allow_rotation=1;
799             allow_translation=1;
800             sample_size=2;
801             break;
802         case DB_HOMOGRAPHY_TYPE_SIMILARITY_U:
803             orientation_preserving=0;
804             allow_scaling=1;
805             allow_rotation=1;
806             allow_translation=1;
807             sample_size=3;
808             break;
809         case DB_HOMOGRAPHY_TYPE_TRANSLATION:
810             orientation_preserving=1;
811             allow_scaling=0;
812             allow_rotation=0;
813             allow_translation=1;
814             sample_size=1;
815             break;
816         case DB_HOMOGRAPHY_TYPE_ROTATION:
817             orientation_preserving=1;
818             allow_scaling=0;
819             allow_rotation=1;
820             allow_translation=0;
821             sample_size=1;
822             break;
823         case DB_HOMOGRAPHY_TYPE_ROTATION_U:
824             orientation_preserving=0;
825             allow_scaling=0;
826             allow_rotation=1;
827             allow_translation=0;
828             sample_size=2;
829             break;
830         case DB_HOMOGRAPHY_TYPE_SCALING:
831             orientation_preserving=1;
832             allow_scaling=1;
833             allow_rotation=0;
834             allow_translation=0;
835             sample_size=1;
836             break;
837         case DB_HOMOGRAPHY_TYPE_S_T:
838             orientation_preserving=1;
839             allow_scaling=1;
840             allow_rotation=0;
841             allow_translation=1;
842             sample_size=2;
843             break;
844         case DB_HOMOGRAPHY_TYPE_R_T:
845             orientation_preserving=1;
846             allow_scaling=0;
847             allow_rotation=1;
848             allow_translation=1;
849             sample_size=2;
850             break;
851         case DB_HOMOGRAPHY_TYPE_R_S:
852             orientation_preserving=1;
853             allow_scaling=1;
854             allow_rotation=0;
855             allow_translation=0;
856             sample_size=1;
857             break;
858         }
859 
860         if(point_count>=sample_size) for(i=0;i<nr_samples;i++)
861         {
862             db_RandomSample(s,3,point_count,r_seed);
863             X[0]= &x_i[s[0]<<1];
864             X[1]= &x_i[s[1]<<1];
865             X[2]= &x_i[s[2]<<1];
866             Xp[0]= &xp_i[s[0]<<1];
867             Xp[1]= &xp_i[s[1]<<1];
868             Xp[2]= &xp_i[s[2]<<1];
869             db_StitchSimilarity2D(&hyp_H_array[9*hyp_count],Xp,X,sample_size,orientation_preserving,
870                                   allow_scaling,allow_rotation,allow_translation);
871             hyp_count++;
872         }
873         break;
874 
875     case DB_HOMOGRAPHY_TYPE_CAMROTATION:
876         if(point_count>=2) for(i=0;i<nr_samples;i++)
877         {
878             db_RandomSample(s,2,point_count,r_seed);
879             db_StitchCameraRotation_2Points(&hyp_H_array[9*hyp_count],
880                                       &x_h[3*s[0]],&x_h[3*s[1]],
881                                       &xp_h[3*s[0]],&xp_h[3*s[1]]);
882             hyp_count++;
883         }
884         break;
885 
886     case DB_HOMOGRAPHY_TYPE_CAMROTATION_F:
887         if(point_count>=3) for(i=0;i<nr_samples;i++)
888         {
889             db_RandomSample(s,3,point_count,r_seed);
890             hyp_count+=db_StitchRotationCommonFocalLength_3Points(&hyp_H_array[9*hyp_count],
891                                       &x_h[3*s[0]],&x_h[3*s[1]],&x_h[3*s[2]],
892                                       &xp_h[3*s[0]],&xp_h[3*s[1]],&xp_h[3*s[2]]);
893         }
894         break;
895 
896     case DB_HOMOGRAPHY_TYPE_CAMROTATION_F_UD:
897         if(point_count>=3) for(i=0;i<nr_samples;i++)
898         {
899             db_RandomSample(s,3,point_count,r_seed);
900             hyp_count+=db_StitchRotationCommonFocalLength_3Points(&hyp_H_array[9*hyp_count],
901                                       &x_h[3*s[0]],&x_h[3*s[1]],&x_h[3*s[2]],
902                                       &xp_h[3*s[0]],&xp_h[3*s[1]],&xp_h[3*s[2]],NULL,0);
903         }
904         break;
905 
906     case DB_HOMOGRAPHY_TYPE_AFFINE:
907         if(point_count>=3) for(i=0;i<nr_samples;i++)
908         {
909             db_RandomSample(s,3,point_count,r_seed);
910             db_StitchAffine2D_3Points(&hyp_H_array[9*hyp_count],
911                                       &x_h[3*s[0]],&x_h[3*s[1]],&x_h[3*s[2]],
912                                       &xp_h[3*s[0]],&xp_h[3*s[1]],&xp_h[3*s[2]]);
913             hyp_count++;
914         }
915         break;
916 
917     case DB_HOMOGRAPHY_TYPE_PROJECTIVE:
918     default:
919         if(point_count>=4) for(i=0;i<nr_samples;i++)
920         {
921             db_RandomSample(s,4,point_count,r_seed);
922             db_StitchProjective2D_4Points(&hyp_H_array[9*hyp_count],
923                                       &x_h[3*s[0]],&x_h[3*s[1]],&x_h[3*s[2]],&x_h[3*s[3]],
924                                       &xp_h[3*s[0]],&xp_h[3*s[1]],&xp_h[3*s[2]],&xp_h[3*s[3]]);
925             hyp_count++;
926         }
927     }
928 
929     if(hyp_count)
930     {
931         /*Count cost in chunks and decimate hypotheses
932         until only one remains or the correspondences are
933         exhausted*/
934         for(i=0;i<hyp_count;i++)
935         {
936             hyp_perm[i]=i;
937             hyp_cost_array[i]=0.0;
938         }
939         for(i=0,last_hyp=hyp_count-1;(last_hyp>0) && (i<point_count);i+=chunk_size)
940         {
941             /*Update cost with the next chunk*/
942             last_corr=db_mini(i+chunk_size-1,point_count-1);
943             for(j=0;j<=last_hyp;j++)
944             {
945                 hyp_point=hyp_H_array+9*hyp_perm[j];
946                 for(c=i;c<=last_corr;)
947                 {
948                     /*Take log of product of ten reprojection
949                     errors to reduce nr of expensive log operations*/
950                     if(c+9<=last_corr)
951                     {
952                         x_i_temp=x_i+(c<<1);
953                         xp_i_temp=xp_i+(c<<1);
954 
955                         acc=db_ExpCauchyInhomogenousHomographyError(xp_i_temp,hyp_point,x_i_temp,one_over_scale2);
956                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+2,hyp_point,x_i_temp+2,one_over_scale2);
957                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+4,hyp_point,x_i_temp+4,one_over_scale2);
958                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+6,hyp_point,x_i_temp+6,one_over_scale2);
959                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+8,hyp_point,x_i_temp+8,one_over_scale2);
960                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+10,hyp_point,x_i_temp+10,one_over_scale2);
961                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+12,hyp_point,x_i_temp+12,one_over_scale2);
962                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+14,hyp_point,x_i_temp+14,one_over_scale2);
963                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+16,hyp_point,x_i_temp+16,one_over_scale2);
964                         acc*=db_ExpCauchyInhomogenousHomographyError(xp_i_temp+18,hyp_point,x_i_temp+18,one_over_scale2);
965                         c+=10;
966                     }
967                     else
968                     {
969                         for(acc=1.0;c<=last_corr;c++)
970                         {
971                             acc*=db_ExpCauchyInhomogenousHomographyError(xp_i+(c<<1),hyp_point,x_i+(c<<1),one_over_scale2);
972                         }
973                     }
974                     hyp_cost_array[j]+=log(acc);
975                 }
976             }
977             if (chunk_size<point_count){
978                 /*Prune out half of the hypotheses*/
979                 new_last_hyp=(last_hyp+1)/2-1;
980                 pivot=db_LeanQuickSelect(hyp_cost_array,last_hyp+1,new_last_hyp,temp_select);
981                 for(j=0,c=0;(j<=last_hyp) && (c<=new_last_hyp);j++)
982                 {
983                     if(hyp_cost_array[j]<=pivot)
984                     {
985                         hyp_cost_array[c]=hyp_cost_array[j];
986                         hyp_perm[c]=hyp_perm[j];
987                         c++;
988                     }
989                 }
990                 last_hyp=new_last_hyp;
991             }
992         }
993         /*Find the best hypothesis*/
994         lowest_cost=hyp_cost_array[0];
995         best_pos=0;
996         for(j=1;j<=last_hyp;j++)
997         {
998             if(hyp_cost_array[j]<lowest_cost)
999             {
1000                 lowest_cost=hyp_cost_array[j];
1001                 best_pos=j;
1002             }
1003         }
1004 
1005         /*Move the best hypothesis*/
1006         db_Copy9(H_temp,hyp_H_array+9*hyp_perm[best_pos]);
1007 
1008         // outlier removal
1009         if (outlierremoveflagE) // no polishment needed
1010         {
1011             point_count_new = db_RemoveOutliers_Homography(H_temp,x_i,xp_i,wp,im,im_p,im_r,im_raw,im_raw_p,point_count,one_over_scale2);
1012         }
1013         else
1014         {
1015             /*Polish*/
1016             switch(homography_type)
1017             {
1018             case DB_HOMOGRAPHY_TYPE_SIMILARITY:
1019             case DB_HOMOGRAPHY_TYPE_SIMILARITY_U:
1020             case DB_HOMOGRAPHY_TYPE_TRANSLATION:
1021             case DB_HOMOGRAPHY_TYPE_ROTATION:
1022             case DB_HOMOGRAPHY_TYPE_ROTATION_U:
1023             case DB_HOMOGRAPHY_TYPE_SCALING:
1024             case DB_HOMOGRAPHY_TYPE_S_T:
1025             case DB_HOMOGRAPHY_TYPE_R_T:
1026             case DB_HOMOGRAPHY_TYPE_R_S:
1027             case DB_HOMOGRAPHY_TYPE_AFFINE:
1028             case DB_HOMOGRAPHY_TYPE_PROJECTIVE:
1029             case DB_HOMOGRAPHY_TYPE_CAMROTATION_F:
1030             case DB_HOMOGRAPHY_TYPE_CAMROTATION_F_UD:
1031                 db_RobCamRotation_Polish_Generic(H_temp,db_mini(point_count,max_points),homography_type,x_i,xp_i,one_over_scale2,max_iterations);
1032                 break;
1033             case DB_HOMOGRAPHY_TYPE_CAMROTATION:
1034                 db_RobCamRotation_Polish(H_temp,db_mini(point_count,max_points),x_i,xp_i,one_over_scale2,max_iterations);
1035                 break;
1036             }
1037 
1038         }
1039 
1040     }
1041     else db_Identity3x3(H_temp);
1042 
1043     switch(homography_type)
1044     {
1045     case DB_HOMOGRAPHY_TYPE_PROJECTIVE:
1046         if(stat) stat->nr_parameters=8;
1047         break;
1048     case DB_HOMOGRAPHY_TYPE_AFFINE:
1049         if(stat) stat->nr_parameters=6;
1050         break;
1051     case DB_HOMOGRAPHY_TYPE_SIMILARITY:
1052     case DB_HOMOGRAPHY_TYPE_SIMILARITY_U:
1053     case DB_HOMOGRAPHY_TYPE_CAMROTATION_F:
1054     case DB_HOMOGRAPHY_TYPE_CAMROTATION_F_UD:
1055         if(stat) stat->nr_parameters=4;
1056         break;
1057     case DB_HOMOGRAPHY_TYPE_CAMROTATION:
1058         if(stat) stat->nr_parameters=3;
1059         break;
1060     case DB_HOMOGRAPHY_TYPE_TRANSLATION:
1061     case DB_HOMOGRAPHY_TYPE_S_T:
1062     case DB_HOMOGRAPHY_TYPE_R_T:
1063     case DB_HOMOGRAPHY_TYPE_R_S:
1064         if(stat) stat->nr_parameters=2;
1065         break;
1066     case DB_HOMOGRAPHY_TYPE_ROTATION:
1067     case DB_HOMOGRAPHY_TYPE_ROTATION_U:
1068     case DB_HOMOGRAPHY_TYPE_SCALING:
1069         if(stat) stat->nr_parameters=1;
1070         break;
1071     }
1072 
1073     db_RobImageHomography_Statistics(H_temp,db_mini(point_count,max_points),x_i,xp_i,one_over_scale2,stat);
1074 
1075     /*Put on the calibration matrices*/
1076     db_Multiply3x3_3x3(H_temp2,H_temp,K_inv);
1077     db_Multiply3x3_3x3(H,Kp,H_temp2);
1078 
1079     if (finalNumE)
1080         *finalNumE = point_count_new;
1081 
1082 }
1083