39 #include <visp3/core/vpColVector.h> 40 #include <visp3/core/vpRansac.h> 41 #include <visp3/vision/vpHomography.h> 43 #include <visp3/core/vpDisplay.h> 44 #include <visp3/core/vpImage.h> 45 #include <visp3/core/vpMeterPixelConversion.h> 54 #ifndef DOXYGEN_SHOULD_SKIP_THIS 56 bool iscolinear(
double *x1,
double *x2,
double *x3);
59 bool iscolinear(
double *x1,
double *x2,
double *x3)
77 bool vpHomography::degenerateConfiguration(
vpColVector &x,
unsigned int *ind,
double threshold_area)
82 for (i = 1; i < 4; i++)
83 for (j = 0; j < i; j++)
87 unsigned int n = x.
getRows() / 4;
91 for (i = 0; i < 4; i++) {
92 pb[i][0] = x[2 * ind[i]];
93 pb[i][1] = x[2 * ind[i] + 1];
96 pa[i][0] = x[2 * n + 2 * ind[i]];
97 pa[i][1] = x[2 * n + 2 * ind[i] + 1];
103 double area012 = (-pa[j][0] * pa[i][1] + pa[k][0] * pa[i][1] + pa[i][0] * pa[j][1] - pa[k][0] * pa[j][1] +
104 -pa[i][0] * pa[k][1] + pa[1][j] * pa[k][1]);
108 double area013 = (-pa[j][0] * pa[i][1] + pa[k][0] * pa[i][1] + pa[i][0] * pa[j][1] - pa[k][0] * pa[j][1] +
109 -pa[i][0] * pa[k][1] + pa[1][j] * pa[k][1]);
113 double area023 = (-pa[j][0] * pa[i][1] + pa[k][0] * pa[i][1] + pa[i][0] * pa[j][1] - pa[k][0] * pa[j][1] +
114 -pa[i][0] * pa[k][1] + pa[1][j] * pa[k][1]);
118 double area123 = (-pa[j][0] * pa[i][1] + pa[k][0] * pa[i][1] + pa[i][0] * pa[j][1] - pa[k][0] * pa[j][1] +
119 -pa[i][0] * pa[k][1] + pa[1][j] * pa[k][1]);
121 double sum_area = area012 + area013 + area023 + area123;
123 return ((sum_area < threshold_area) ||
124 (iscolinear(pa[0], pa[1], pa[2]) || iscolinear(pa[0], pa[1], pa[3]) || iscolinear(pa[0], pa[2], pa[3]) ||
125 iscolinear(pa[1], pa[2], pa[3]) || iscolinear(pb[0], pb[1], pb[2]) || iscolinear(pb[0], pb[1], pb[3]) ||
126 iscolinear(pb[0], pb[2], pb[3]) || iscolinear(pb[1], pb[2], pb[3])));
140 bool vpHomography::degenerateConfiguration(
vpColVector &x,
unsigned int *ind)
142 for (
unsigned int i = 1; i < 4; i++)
143 for (
unsigned int j = 0; j < i; j++)
144 if (ind[i] == ind[j])
147 unsigned int n = x.
getRows() / 4;
150 unsigned int n2 = 2 * n;
151 for (
unsigned int i = 0; i < 4; i++) {
152 unsigned int ind2 = 2 * ind[i];
154 pb[i][1] = x[ind2 + 1];
157 pa[i][0] = x[n2 + ind2];
158 pa[i][1] = x[n2 + ind2 + 1];
161 return (iscolinear(pa[0], pa[1], pa[2]) || iscolinear(pa[0], pa[1], pa[3]) || iscolinear(pa[0], pa[2], pa[3]) ||
162 iscolinear(pa[1], pa[2], pa[3]) || iscolinear(pb[0], pb[1], pb[2]) || iscolinear(pb[0], pb[1], pb[3]) ||
163 iscolinear(pb[0], pb[2], pb[3]) || iscolinear(pb[1], pb[2], pb[3]));
165 bool vpHomography::degenerateConfiguration(
const std::vector<double> &xb,
const std::vector<double> &yb,
166 const std::vector<double> &xa,
const std::vector<double> &ya)
168 unsigned int n = (
unsigned int)xb.
size();
172 std::vector<vpColVector> pa(n), pb(n);
173 for (
unsigned i = 0; i < n; i++) {
184 for (
unsigned int i = 0; i < n - 2; i++) {
185 for (
unsigned int j = i + 1; j < n - 1; j++) {
186 for (
unsigned int k = j + 1; k < n; k++) {
187 if (isColinear(pa[i], pa[j], pa[k])) {
190 if (isColinear(pb[i], pb[j], pb[k])) {
201 unsigned int n = x.
getRows() / 4;
202 std::vector<double> xa(4), xb(4);
203 std::vector<double> ya(4), yb(4);
204 unsigned int n2 = n * 2;
205 for (
unsigned int i = 0; i < 4; i++) {
206 unsigned int ind2 = 2 * ind[i];
210 xa[i] = x[n2 + ind2];
211 ya[i] = x[n2 + ind2 + 1];
222 for (
unsigned int i = 0; i < 9; i++) {
231 unsigned int n = x.
getRows() / 4;
232 unsigned int n2 = n * 2;
239 for (
unsigned int i = 0; i < n; i++) {
240 unsigned int i2 = 2 * i;
243 pb[i][1] = x[i2 + 1];
247 pa[i][0] = x[n2 + i2];
248 pa[i][1] = x[n2 + i2 + 1];
254 for (
unsigned int i = 0; i < 9; i++) {
263 for (
unsigned int i = 0; i < n; i++) {
266 d[i] = sqrt((pa[i] - Hpb).sumSquare());
274 #endif //#ifndef DOXYGEN_SHOULD_SKIP_THIS 276 void vpHomography::initRansac(
unsigned int n,
double *xb,
double *yb,
double *xa,
double *ya,
vpColVector &x)
279 unsigned int n2 = n * 2;
280 for (
unsigned int i = 0; i < n; i++) {
281 unsigned int i2 = 2 * i;
285 x[n2 + i2 + 1] = ya[i];
318 bool vpHomography::ransac(
const std::vector<double> &xb,
const std::vector<double> &yb,
const std::vector<double> &xa,
319 const std::vector<double> &ya,
vpHomography &aHb, std::vector<bool> &inliers,
320 double &residual,
unsigned int nbInliersConsensus,
double threshold,
bool normalization)
322 unsigned int n = (
unsigned int)xb.size();
323 if (yb.size() != n || xa.size() != n || ya.size() != n)
332 std::vector<unsigned int> best_consensus;
333 std::vector<unsigned int> cur_consensus;
334 std::vector<unsigned int> cur_outliers;
335 std::vector<unsigned int> cur_randoms;
337 std::vector<unsigned int> rand_ind;
339 unsigned int nbMinRandom = 4;
340 unsigned int ransacMaxTrials = 1000;
341 unsigned int maxDegenerateIter = 1000;
343 unsigned int nbTrials = 0;
344 unsigned int nbDegenerateIter = 0;
345 unsigned int nbInliers = 0;
347 bool foundSolution =
false;
349 std::vector<double> xa_rand(nbMinRandom);
350 std::vector<double> ya_rand(nbMinRandom);
351 std::vector<double> xb_rand(nbMinRandom);
352 std::vector<double> yb_rand(nbMinRandom);
354 if (inliers.size() != n)
357 while (nbTrials < ransacMaxTrials && nbInliers < nbInliersConsensus) {
358 cur_outliers.clear();
361 bool degenerate =
true;
362 while (degenerate ==
true) {
363 std::vector<bool> usedPt(n,
false);
366 for (
unsigned int i = 0; i < nbMinRandom; i++) {
368 unsigned int r = (
unsigned int)ceil(random() * n) - 1;
370 r = (
unsigned int)ceil(random() * n) - 1;
373 rand_ind.push_back(r);
382 if (!vpHomography::degenerateConfiguration(xb_rand, yb_rand, xa_rand, ya_rand)) {
392 if (nbDegenerateIter > maxDegenerateIter) {
403 for (
unsigned int i = 0; i < nbMinRandom; i++) {
413 r += (a - c).sumSquare();
418 r = sqrt(r / nbMinRandom);
421 unsigned int nbInliersCur = 0;
422 for (
unsigned int i = 0; i < n; i++) {
432 double error = sqrt((a - c).sumSquare());
433 if (error <= threshold) {
435 cur_consensus.push_back(i);
438 cur_outliers.push_back(i);
444 if (nbInliersCur > nbInliers) {
445 foundSolution =
true;
446 best_consensus = cur_consensus;
447 nbInliers = nbInliersCur;
450 cur_consensus.clear();
454 if (nbTrials >= ransacMaxTrials) {
455 vpERROR_TRACE(
"Ransac reached the maximum number of trials");
456 foundSolution =
true;
461 if (nbInliers >= nbInliersConsensus) {
462 std::vector<double> xa_best(best_consensus.size());
463 std::vector<double> ya_best(best_consensus.size());
464 std::vector<double> xb_best(best_consensus.size());
465 std::vector<double> yb_best(best_consensus.size());
467 for (
unsigned i = 0; i < best_consensus.size(); i++) {
468 xa_best[i] = xa[best_consensus[i]];
469 ya_best[i] = ya[best_consensus[i]];
470 xb_best[i] = xb[best_consensus[i]];
471 yb_best[i] = yb[best_consensus[i]];
479 for (
unsigned int i = 0; i < best_consensus.size(); i++) {
489 residual += (a - c).sumSquare();
492 residual = sqrt(residual / best_consensus.size());
Implementation of a matrix and operations on matrices.
static vpColVector cross(const vpColVector &a, const vpColVector &b)
error that can be emited by ViSP classes.
Type * data
Address of the first element of the data array.
unsigned int size() const
Return the number of elements of the 2D array.
static void HLM(const std::vector< double > &xb, const std::vector< double > &yb, const std::vector< double > &xa, const std::vector< double > &ya, bool isplanar, vpHomography &aHb)
Implementation of an homography and operations on homographies.
static bool ransac(const std::vector< double > &xb, const std::vector< double > &yb, const std::vector< double > &xa, const std::vector< double > &ya, vpHomography &aHb, std::vector< bool > &inliers, double &residual, unsigned int nbInliersConsensus, double threshold, bool normalization=true)
unsigned int getRows() const
static void DLT(const std::vector< double > &xb, const std::vector< double > &yb, const std::vector< double > &xa, const std::vector< double > &ya, vpHomography &aHb, bool normalization=true)
void resize(unsigned int i, bool flagNullify=true)
Implementation of column vector and the associated operations.
Class for generating random numbers with uniform probability density.