bool FeatureCoordinates::getDepthFromTriangulation(const FeatureCoordinates& other, const V3D& C2rC2C1, const QPD& qC2C1, FeatureDistance& d) { Eigen::Matrix<double,3,2> B; B << qC2C1.rotate(get_nor().getVec()), other.get_nor().getVec(); const Eigen::Matrix2d BtB = B.transpose() * B; if(BtB.determinant() < 0.000001) { // Projection rays almost parallel. return false; } const Eigen::Vector2d dv = - BtB.inverse() * B.transpose() * C2rC2C1; d.setParameter(fabs(dv[0])); return true; }
double covToSDPixels(const Eigen::Matrix2d & S) { const double dProductOfEigenvectors = S.determinant(); if(IS_DEBUG) CHECK(dProductOfEigenvectors < 0, "cov matrix not positive definite"); return pow(dProductOfEigenvectors, 0.25); //Approx. sigma in pixels }
void Deformable::projectPositionsCluster(std::vector<int> cluster, int cluster_indx) { int numVertices = cluster.size(); if (numVertices <= 1) return; int i;//,j,k; double beta_cluster =params.lbeta.at(cluster_indx); // center of mass Eigen::Vector2d cm, originalCm; cm.setZero(); originalCm.setZero(); double mass = 0.0; int indx; for (i = 0; i < numVertices; i++) { indx= cluster.at(i); double m = mMasses(indx,0); if (mFixed(indx,0)) m *= 100.0; mass += m; cm += mNewPos.row(indx) * m; originalCm += mOriginalPos.row(indx) * m; //std::cout<<"before: "<<mNewPos.row(indx)<<std::endl; } cm /= mass; originalCm /= mass; Eigen::Matrix2d Apq; Eigen::Matrix2d Aqq; Eigen::Vector2d p; Eigen::Vector2d q; Apq.setZero(); Aqq.setZero(); for (i = 0; i < numVertices; i++) { indx= cluster.at(i); p(0) = mNewPos(indx,0) - cm(0); p(1) = mNewPos(indx,1) - cm(1); q(0) = mOriginalPos(indx,0) - originalCm(0); q(1) = mOriginalPos(indx,1) - originalCm(1); double m = mMasses(indx,0); Apq += m*p*q.transpose(); Aqq += m*q*q.transpose(); } if (!params.allowFlip && Apq.determinant() < 0.0f) { // prevent from flipping Apq(0,1) = -Apq(0,1); Apq(1,1) = -Apq(1,1); } Eigen::Matrix2d R; Eigen::JacobiSVD<Eigen::MatrixXd> svd(Apq, Eigen::ComputeThinU | Eigen::ComputeThinV); Eigen::MatrixXd U = svd.matrixU(); Eigen::MatrixXd V = svd.matrixV(); R = U*V.transpose(); if (!params.quadraticMatch) { // --------- linear match Eigen::Matrix2d A = Aqq; A = Apq*A.inverse(); if (params.volumeConservation) { double det = A.determinant(); if (det != 0.0) { det = 1.0 / sqrt(fabs(det)); if (det > 2.0) det = 2.0; A = A*det; } } Eigen::Matrix2d T = R * (1.0 - beta_cluster) + A * beta_cluster; std::cout<<"cluster's beta "<<beta_cluster<<std::endl; for (i = 0; i < numVertices; i++) { int indx= cluster.at(i); indxCount.at(indx) +=1; if (mFixed(indx)) continue; q(0) = mOriginalPos(indx,0) - originalCm(0); q(1) = mOriginalPos(indx,1) - originalCm(1); Eigen::Vector2d Tq = T*q; mGoalPos(indx,0) = Tq(0)+cm(0); mGoalPos(indx,1) = Tq(1)+cm(1); mNewPos.row(indx) += (mGoalPos.row(indx) - mNewPos.row(indx)) * params.alpha; mGoalPos_sum.row(indx) += mNewPos.row(indx); } } }
void Deformable::projectPositions() { if (mNumVertices <= 1) return; int i;//,j,k; // center of mass Eigen::Vector2d cm, originalCm; cm.setZero(); originalCm.setZero(); double mass = 0.0; for (i = 0; i < mNumVertices; i++) { double m = mMasses(i,0); if (mFixed(i,0)) m *= 1000.0; mass += m; cm += mNewPos.row(i) * m; originalCm += mOriginalPos.row(i) * m; } //std::cout<<std::endl; cm /= mass; originalCm /= mass; Eigen::Matrix2d Apq; Eigen::Matrix2d Aqq; Eigen::Vector2d p; Eigen::Vector2d q; Apq.setZero(); Aqq.setZero(); for (i = 0; i < mNumVertices; i++) { p(0) = mNewPos(i,0) - cm(0); p(1) = mNewPos(i,1) - cm(1); q(0) = mOriginalPos(i,0) - originalCm(0); q(1) = mOriginalPos(i,1) - originalCm(1); double m = mMasses(i,0); Apq += m*p*q.transpose(); Aqq += m*q*q.transpose(); } /*if (!params.allowFlip && Apq.determinant() < 0.0f) { // prevent from flipping Apq(0,1) = -Apq(0,1); Apq(1,1) = -Apq(1,1); }*/ //std::cout<<Apq<<std::endl; Eigen::Matrix2d R; Eigen::JacobiSVD<Eigen::MatrixXd> svd(Apq, Eigen::ComputeThinU | Eigen::ComputeThinV); Eigen::MatrixXd U = svd.matrixU(); Eigen::MatrixXd V = svd.matrixV(); R = U*V.transpose(); if (!params.quadraticMatch) { // --------- linear match Eigen::Matrix2d A = Aqq; Eigen::Matrix2d A_=A.inverse(); /*std::cout<<A_.row(0)<<std::endl; std::cout<<A_.row(1)<<std::endl;*/ A = Apq*A_; if (params.volumeConservation) { double det = A.determinant(); if(det<0) det=-det; if (det != 0.0) { det = 1.0 / sqrt(fabs(det)); if (det > 2.0) det = 2.0; A *= det; } } float one_beta =1.0 - params.beta; Eigen::Matrix2d T = R * one_beta; A=A*params.beta; T = T + A; for (i = 0; i < mNumVertices; i++) { if (mFixed(i)) continue; q(0) = mOriginalPos(i,0) - originalCm(0); q(1) = mOriginalPos(i,1) - originalCm(1); Eigen::Vector2d Tq = T*q; mGoalPos(i,0) = Tq(0)+cm(0); mGoalPos(i,1) = Tq(1)+cm(1); //mGoalPos.row(i)=(R * (1.0f - params.beta) + A * params.beta)*q+cm; mNewPos.row(i) += (mGoalPos.row(i) - mNewPos.row(i)) * params.alpha; //std::cout<<T.row(0)<<std::endl; //std::cout<<T.row(1)<<std::endl; } } }