int main(int, char**) { cout.precision(3); SelfAdjointEigenSolver<Matrix4f> es; Matrix4f X = Matrix4f::Random(4,4); Matrix4f A = X + X.transpose(); es.compute(A); cout << "The eigenvalues of A are: " << es.eigenvalues().transpose() << endl; es.compute(A + Matrix4f::Identity(4,4)); // re-use es to compute eigenvalues of A+I cout << "The eigenvalues of A+I are: " << es.eigenvalues().transpose() << endl; return 0; }
void CMT::WhiteningTransform::initialize(const ArrayXXd& input, int dimOut) { if(input.cols() < input.rows()) throw Exception("Too few inputs to compute whitening transform."); mMeanIn = input.rowwise().mean(); // compute covariances MatrixXd covXX = covariance(input); // input whitening SelfAdjointEigenSolver<MatrixXd> eigenSolver; eigenSolver.compute(covXX); Array<double, 1, Dynamic> eigenvalues = eigenSolver.eigenvalues(); MatrixXd eigenvectors = eigenSolver.eigenvectors(); // don't whiten directions with near-zero variance for(int i = 0; i < eigenvalues.size(); ++i) if(eigenvalues[i] < 1e-7) eigenvalues[i] = 1.; mPreIn = (eigenvectors.array().rowwise() * eigenvalues.sqrt().cwiseInverse()).matrix() * eigenvectors.transpose(); mPreInInv = (eigenvectors.array().rowwise() * eigenvalues.sqrt()).matrix() * eigenvectors.transpose(); mMeanOut = VectorXd::Zero(dimOut); mPreOut = MatrixXd::Identity(dimOut, dimOut); mPreOutInv = MatrixXd::Identity(dimOut, dimOut); mPredictor = MatrixXd::Zero(dimOut, input.rows()); mGradTransform = MatrixXd::Zero(dimOut, input.rows()); mLogJacobian = 1.; }
void ctBdG:: Initialize_Euabv(){ SelfAdjointEigenSolver<MatrixXcd> ces; distribution(_NK2); int nkx, nky, nk; for (int ig = 0; ig < _size; ++ig) { if (ig==_rank) { _bdg_E.resize(recvcount,4); _bdg_u.resize(recvcount,4); _bdg_a.resize(recvcount,4); _bdg_b.resize(recvcount,4); _bdg_v.resize(recvcount,4); local_Delta_k_r = new double[recvcount]; local_Delta_k_i = new double[recvcount]; for (int i = 0; i < recvcount; ++i) { nk = recvbuf[i]; nkx = nk%_NK; nky = int(nk/_NK); construct_BdG(_gauss_k[nkx],_gauss_k[nky], _mu, _hi); ces.compute(_bdg); _bdg_E.row(i) = ces.eigenvalues(); _bdg_u.row(i) = ces.eigenvectors().row(0); _bdg_a.row(i) = ces.eigenvectors().row(1); _bdg_b.row(i) = ces.eigenvectors().row(2); _bdg_v.row(i) = ces.eigenvectors().row(3); } } } }
void MaterialFitting::solveByNNLS(){ const SXMatrix M1 = assembleObjMatrix(); vector<SX> smooth_funs; computeSmoothObjFunctions(smooth_funs); SXMatrix obj_fun_m(M1.size1()*M1.size2()+smooth_funs.size(),1); for (int i = 0; i < M1.size1(); ++i){ for (int j = 0; j < M1.size2(); ++j) obj_fun_m.elem(i*M1.size2()+j,0) = M1.elem(i,j); } for (int i = 0; i < smooth_funs.size(); ++i){ obj_fun_m.elem(M1.size2()*M1.size2()+i,0) = smooth_funs[i]; } VSX variable_x; initAllVariables(variable_x); CasADi::SXFunction g_fun = CasADi::SXFunction(variable_x,obj_fun_m); g_fun.init(); VectorXd x0(variable_x.size()), b; x0.setZero(); CASADI::evaluate(g_fun, x0, b); b = -b; MatrixXd J = CASADI::convert<double>(g_fun.jac()); assert_eq(J.rows(), b.size()); assert_eq(J.cols(), x0.size()); VectorXd x(b.size()), w(J.cols()), zz(J.rows()); VectorXi index(J.cols()*2); getInitValue(x); int exit_code = 0; double residual = 1e-18; nnls(&J(0,0), J.rows(), J.rows(), J.cols(), &b[0], &x[0], &residual, &w[0], &zz[0], &index[0], &exit_code); INFO_LOG("residual: " << residual); print_NNLS_exit_code(exit_code); rlst.resize(x.size()); for (int i = 0; i < x.size(); ++i){ rlst[i] = x[i]; } const MatrixXd H = J.transpose()*J; SelfAdjointEigenSolver<MatrixXd> es; es.compute(H); cout << "The eigenvalues of H are: " << es.eigenvalues().transpose() << endl; }
bool IsotropicMaxStressDamage(const Matrix3d S, const double maxStress) { /* * compute Eigenvalues of strain matrix */ SelfAdjointEigenSolver < Matrix3d > es; es.compute(S); // compute eigenvalue and eigenvectors of strain double max_eigenvalue = es.eigenvalues().maxCoeff(); if (max_eigenvalue > maxStress) { return true; } else { return false; } }
void MaterialFitting::solveByLinearSolver(){ MatrixXd H; VectorXd g; hessGrad(H,g); SelfAdjointEigenSolver<MatrixXd> es; es.compute(H); cout << "H.norm() = " << H.norm() << endl; cout << "The eigenvalues of H are: \n" << es.eigenvalues().transpose() << endl; const VectorXd x = H.lu().solve(-g); rlst.resize(x.size()); for (int i = 0; i < x.size(); ++i) rlst[i] = x[i]; cout<< "\n(H*x+g).norm() = " << (H*x+g).norm() << "\n\n"; }
void drwnNNGraphMLearner::subGradientStep(const MatrixXd& G, double alpha) { DRWN_FCN_TIC; // gradient step _M -= alpha * G; // project onto psd SelfAdjointEigenSolver<MatrixXd> es; es.compute(_M); const VectorXd d = es.eigenvalues().real(); if ((d.array() < 0.0).any()) { const MatrixXd V = es.eigenvectors(); _M = V * d.cwiseMax(VectorXd::Constant(d.rows(), DRWN_EPSILON)).asDiagonal() * V.inverse(); } DRWN_FCN_TOC; }
template<typename MatrixType> void selfadjointeigensolver(const MatrixType& m) { typedef typename MatrixType::Index Index; /* this test covers the following files: EigenSolver.h, SelfAdjointEigenSolver.h (and indirectly: Tridiagonalization.h) */ Index rows = m.rows(); Index cols = m.cols(); typedef typename MatrixType::Scalar Scalar; typedef typename NumTraits<Scalar>::Real RealScalar; RealScalar largerEps = 10*test_precision<RealScalar>(); MatrixType a = MatrixType::Random(rows,cols); MatrixType a1 = MatrixType::Random(rows,cols); MatrixType symmA = a.adjoint() * a + a1.adjoint() * a1; MatrixType symmC = symmA; svd_fill_random(symmA,Symmetric); symmA.template triangularView<StrictlyUpper>().setZero(); symmC.template triangularView<StrictlyUpper>().setZero(); MatrixType b = MatrixType::Random(rows,cols); MatrixType b1 = MatrixType::Random(rows,cols); MatrixType symmB = b.adjoint() * b + b1.adjoint() * b1; symmB.template triangularView<StrictlyUpper>().setZero(); CALL_SUBTEST( selfadjointeigensolver_essential_check(symmA) ); SelfAdjointEigenSolver<MatrixType> eiSymm(symmA); // generalized eigen pb GeneralizedSelfAdjointEigenSolver<MatrixType> eiSymmGen(symmC, symmB); SelfAdjointEigenSolver<MatrixType> eiSymmNoEivecs(symmA, false); VERIFY_IS_EQUAL(eiSymmNoEivecs.info(), Success); VERIFY_IS_APPROX(eiSymm.eigenvalues(), eiSymmNoEivecs.eigenvalues()); // generalized eigen problem Ax = lBx eiSymmGen.compute(symmC, symmB,Ax_lBx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmC.template selfadjointView<Lower>() * eiSymmGen.eigenvectors()).isApprox( symmB.template selfadjointView<Lower>() * (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); // generalized eigen problem BAx = lx eiSymmGen.compute(symmC, symmB,BAx_lx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmB.template selfadjointView<Lower>() * (symmC.template selfadjointView<Lower>() * eiSymmGen.eigenvectors())).isApprox( (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); // generalized eigen problem ABx = lx eiSymmGen.compute(symmC, symmB,ABx_lx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmC.template selfadjointView<Lower>() * (symmB.template selfadjointView<Lower>() * eiSymmGen.eigenvectors())).isApprox( (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); eiSymm.compute(symmC); MatrixType sqrtSymmA = eiSymm.operatorSqrt(); VERIFY_IS_APPROX(MatrixType(symmC.template selfadjointView<Lower>()), sqrtSymmA*sqrtSymmA); VERIFY_IS_APPROX(sqrtSymmA, symmC.template selfadjointView<Lower>()*eiSymm.operatorInverseSqrt()); MatrixType id = MatrixType::Identity(rows, cols); VERIFY_IS_APPROX(id.template selfadjointView<Lower>().operatorNorm(), RealScalar(1)); SelfAdjointEigenSolver<MatrixType> eiSymmUninitialized; VERIFY_RAISES_ASSERT(eiSymmUninitialized.info()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvalues()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvectors()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorSqrt()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorInverseSqrt()); eiSymmUninitialized.compute(symmA, false); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvectors()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorSqrt()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorInverseSqrt()); // test Tridiagonalization's methods Tridiagonalization<MatrixType> tridiag(symmC); VERIFY_IS_APPROX(tridiag.diagonal(), tridiag.matrixT().diagonal()); VERIFY_IS_APPROX(tridiag.subDiagonal(), tridiag.matrixT().template diagonal<-1>()); Matrix<RealScalar,Dynamic,Dynamic> T = tridiag.matrixT(); if(rows>1 && cols>1) { // FIXME check that upper and lower part are 0: //VERIFY(T.topRightCorner(rows-2, cols-2).template triangularView<Upper>().isZero()); } VERIFY_IS_APPROX(tridiag.diagonal(), T.diagonal()); VERIFY_IS_APPROX(tridiag.subDiagonal(), T.template diagonal<1>()); VERIFY_IS_APPROX(MatrixType(symmC.template selfadjointView<Lower>()), tridiag.matrixQ() * tridiag.matrixT().eval() * MatrixType(tridiag.matrixQ()).adjoint()); VERIFY_IS_APPROX(MatrixType(symmC.template selfadjointView<Lower>()), tridiag.matrixQ() * tridiag.matrixT() * tridiag.matrixQ().adjoint()); // Test computation of eigenvalues from tridiagonal matrix if(rows > 1) { SelfAdjointEigenSolver<MatrixType> eiSymmTridiag; eiSymmTridiag.computeFromTridiagonal(tridiag.matrixT().diagonal(), tridiag.matrixT().diagonal(-1), ComputeEigenvectors); VERIFY_IS_APPROX(eiSymm.eigenvalues(), eiSymmTridiag.eigenvalues()); VERIFY_IS_APPROX(tridiag.matrixT(), eiSymmTridiag.eigenvectors().real() * eiSymmTridiag.eigenvalues().asDiagonal() * eiSymmTridiag.eigenvectors().real().transpose()); } if (rows > 1) { // Test matrix with NaN symmC(0,0) = std::numeric_limits<typename MatrixType::RealScalar>::quiet_NaN(); SelfAdjointEigenSolver<MatrixType> eiSymmNaN(symmC); VERIFY_IS_EQUAL(eiSymmNaN.info(), NoConvergence); } }
template<typename MatrixType> void selfadjointeigensolver(const MatrixType& m) { typedef typename MatrixType::Index Index; /* this test covers the following files: EigenSolver.h, SelfAdjointEigenSolver.h (and indirectly: Tridiagonalization.h) */ Index rows = m.rows(); Index cols = m.cols(); typedef typename MatrixType::Scalar Scalar; typedef typename NumTraits<Scalar>::Real RealScalar; typedef Matrix<Scalar, MatrixType::RowsAtCompileTime, 1> VectorType; typedef Matrix<RealScalar, MatrixType::RowsAtCompileTime, 1> RealVectorType; typedef typename std::complex<typename NumTraits<typename MatrixType::Scalar>::Real> Complex; RealScalar largerEps = 10*test_precision<RealScalar>(); MatrixType a = MatrixType::Random(rows,cols); MatrixType a1 = MatrixType::Random(rows,cols); MatrixType symmA = a.adjoint() * a + a1.adjoint() * a1; symmA.template triangularView<StrictlyUpper>().setZero(); MatrixType b = MatrixType::Random(rows,cols); MatrixType b1 = MatrixType::Random(rows,cols); MatrixType symmB = b.adjoint() * b + b1.adjoint() * b1; symmB.template triangularView<StrictlyUpper>().setZero(); SelfAdjointEigenSolver<MatrixType> eiSymm(symmA); // generalized eigen pb GeneralizedSelfAdjointEigenSolver<MatrixType> eiSymmGen(symmA, symmB); #ifdef HAS_GSL if (internal::is_same<RealScalar,double>::value) { // restore symmA and symmB. symmA = MatrixType(symmA.template selfadjointView<Lower>()); symmB = MatrixType(symmB.template selfadjointView<Lower>()); typedef GslTraits<Scalar> Gsl; typename Gsl::Matrix gEvec=0, gSymmA=0, gSymmB=0; typename GslTraits<RealScalar>::Vector gEval=0; RealVectorType _eval; MatrixType _evec; convert<MatrixType>(symmA, gSymmA); convert<MatrixType>(symmB, gSymmB); convert<MatrixType>(symmA, gEvec); gEval = GslTraits<RealScalar>::createVector(rows); Gsl::eigen_symm(gSymmA, gEval, gEvec); convert(gEval, _eval); convert(gEvec, _evec); // test gsl itself ! VERIFY((symmA * _evec).isApprox(_evec * _eval.asDiagonal(), largerEps)); // compare with eigen VERIFY_IS_APPROX(_eval, eiSymm.eigenvalues()); VERIFY_IS_APPROX(_evec.cwiseAbs(), eiSymm.eigenvectors().cwiseAbs()); // generalized pb Gsl::eigen_symm_gen(gSymmA, gSymmB, gEval, gEvec); convert(gEval, _eval); convert(gEvec, _evec); // test GSL itself: VERIFY((symmA * _evec).isApprox(symmB * (_evec * _eval.asDiagonal()), largerEps)); // compare with eigen MatrixType normalized_eivec = eiSymmGen.eigenvectors()*eiSymmGen.eigenvectors().colwise().norm().asDiagonal().inverse(); VERIFY_IS_APPROX(_eval, eiSymmGen.eigenvalues()); VERIFY_IS_APPROX(_evec.cwiseAbs(), normalized_eivec.cwiseAbs()); Gsl::free(gSymmA); Gsl::free(gSymmB); GslTraits<RealScalar>::free(gEval); Gsl::free(gEvec); } #endif VERIFY_IS_EQUAL(eiSymm.info(), Success); VERIFY((symmA.template selfadjointView<Lower>() * eiSymm.eigenvectors()).isApprox( eiSymm.eigenvectors() * eiSymm.eigenvalues().asDiagonal(), largerEps)); VERIFY_IS_APPROX(symmA.template selfadjointView<Lower>().eigenvalues(), eiSymm.eigenvalues()); SelfAdjointEigenSolver<MatrixType> eiSymmNoEivecs(symmA, false); VERIFY_IS_EQUAL(eiSymmNoEivecs.info(), Success); VERIFY_IS_APPROX(eiSymm.eigenvalues(), eiSymmNoEivecs.eigenvalues()); // generalized eigen problem Ax = lBx eiSymmGen.compute(symmA, symmB,Ax_lBx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmA.template selfadjointView<Lower>() * eiSymmGen.eigenvectors()).isApprox( symmB.template selfadjointView<Lower>() * (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); // generalized eigen problem BAx = lx eiSymmGen.compute(symmA, symmB,BAx_lx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmB.template selfadjointView<Lower>() * (symmA.template selfadjointView<Lower>() * eiSymmGen.eigenvectors())).isApprox( (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); // generalized eigen problem ABx = lx eiSymmGen.compute(symmA, symmB,ABx_lx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmA.template selfadjointView<Lower>() * (symmB.template selfadjointView<Lower>() * eiSymmGen.eigenvectors())).isApprox( (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); MatrixType sqrtSymmA = eiSymm.operatorSqrt(); VERIFY_IS_APPROX(MatrixType(symmA.template selfadjointView<Lower>()), sqrtSymmA*sqrtSymmA); VERIFY_IS_APPROX(sqrtSymmA, symmA.template selfadjointView<Lower>()*eiSymm.operatorInverseSqrt()); MatrixType id = MatrixType::Identity(rows, cols); VERIFY_IS_APPROX(id.template selfadjointView<Lower>().operatorNorm(), RealScalar(1)); SelfAdjointEigenSolver<MatrixType> eiSymmUninitialized; VERIFY_RAISES_ASSERT(eiSymmUninitialized.info()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvalues()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvectors()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorSqrt()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorInverseSqrt()); eiSymmUninitialized.compute(symmA, false); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvectors()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorSqrt()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorInverseSqrt()); // test Tridiagonalization's methods Tridiagonalization<MatrixType> tridiag(symmA); // FIXME tridiag.matrixQ().adjoint() does not work VERIFY_IS_APPROX(MatrixType(symmA.template selfadjointView<Lower>()), tridiag.matrixQ() * tridiag.matrixT().eval() * MatrixType(tridiag.matrixQ()).adjoint()); if (rows > 1) { // Test matrix with NaN symmA(0,0) = std::numeric_limits<typename MatrixType::RealScalar>::quiet_NaN(); SelfAdjointEigenSolver<MatrixType> eiSymmNaN(symmA); VERIFY_IS_EQUAL(eiSymmNaN.info(), NoConvergence); } }
CFeatures* CJade::apply(CFeatures* features) { ASSERT(features); SG_REF(features); SGMatrix<float64_t> X = ((CDenseFeatures<float64_t>*)features)->get_feature_matrix(); int n = X.num_rows; int T = X.num_cols; int m = n; Map<MatrixXd> EX(X.matrix,n,T); // Mean center X VectorXd mean = (EX.rowwise().sum() / (float64_t)T); MatrixXd SPX = EX.colwise() - mean; MatrixXd cov = (SPX * SPX.transpose()) / (float64_t)T; #ifdef DEBUG_JADE std::cout << "cov" << std::endl; std::cout << cov << std::endl; #endif // Whitening & Projection onto signal subspace SelfAdjointEigenSolver<MatrixXd> eig; eig.compute(cov); #ifdef DEBUG_JADE std::cout << "eigenvectors" << std::endl; std::cout << eig.eigenvectors() << std::endl; std::cout << "eigenvalues" << std::endl; std::cout << eig.eigenvalues().asDiagonal() << std::endl; #endif // Scaling VectorXd scales = eig.eigenvalues().cwiseSqrt(); MatrixXd B = scales.cwiseInverse().asDiagonal() * eig.eigenvectors().transpose(); #ifdef DEBUG_JADE std::cout << "whitener" << std::endl; std::cout << B << std::endl; #endif // Sphering SPX = B * SPX; // Estimation of the cumulant matrices int dimsymm = (m * ( m + 1)) / 2; // Dim. of the space of real symm matrices int nbcm = dimsymm; // number of cumulant matrices m_cumulant_matrix = SGMatrix<float64_t>(m,m*nbcm); // Storage for cumulant matrices Map<MatrixXd> CM(m_cumulant_matrix.matrix,m,m*nbcm); MatrixXd R(m,m); R.setIdentity(); MatrixXd Qij = MatrixXd::Zero(m,m); // Temp for a cum. matrix VectorXd Xim = VectorXd::Zero(m); // Temp VectorXd Xjm = VectorXd::Zero(m); // Temp VectorXd Xijm = VectorXd::Zero(m); // Temp int Range = 0; for (int im = 0; im < m; im++) { Xim = SPX.row(im); Xijm = Xim.cwiseProduct(Xim); Qij = SPX.cwiseProduct(Xijm.replicate(1,m).transpose()) * SPX.transpose() / (float)T - R - 2*R.col(im)*R.col(im).transpose(); CM.block(0,Range,m,m) = Qij; Range = Range + m; for (int jm = 0; jm < im; jm++) { Xjm = SPX.row(jm); Xijm = Xim.cwiseProduct(Xjm); Qij = SPX.cwiseProduct(Xijm.replicate(1,m).transpose()) * SPX.transpose() / (float)T - R.col(im)*R.col(jm).transpose() - R.col(jm)*R.col(im).transpose(); CM.block(0,Range,m,m) = sqrt(2)*Qij; Range = Range + m; } } #ifdef DEBUG_JADE std::cout << "cumulatant matrices" << std::endl; std::cout << CM << std::endl; #endif // Stack cumulant matrix into ND Array index_t * M_dims = SG_MALLOC(index_t, 3); M_dims[0] = m; M_dims[1] = m; M_dims[2] = nbcm; SGNDArray< float64_t > M(M_dims, 3); for (int i = 0; i < nbcm; i++) { Map<MatrixXd> EM(M.get_matrix(i),m,m); EM = CM.block(0,i*m,m,m); } // Diagonalize SGMatrix<float64_t> Q = CJADiagOrth::diagonalize(M, m_mixing_matrix, tol, max_iter); Map<MatrixXd> EQ(Q.matrix,m,m); EQ = -1 * EQ.inverse(); #ifdef DEBUG_JADE std::cout << "diagonalizer" << std::endl; std::cout << EQ << std::endl; #endif // Separating matrix SGMatrix<float64_t> sep_matrix = SGMatrix<float64_t>(m,m); Map<MatrixXd> C(sep_matrix.matrix,m,m); C = EQ.transpose() * B; // Sort VectorXd A = (B.inverse()*EQ).cwiseAbs2().colwise().sum(); bool swap = false; do { swap = false; for (int j = 1; j < n; j++) { if ( A(j) < A(j-1) ) { std::swap(A(j),A(j-1)); C.col(j).swap(C.col(j-1)); swap = true; } } } while(swap); for (int j = 0; j < m/2; j++) C.row(j).swap( C.row(m-1-j) ); // Fix Signs VectorXd signs = VectorXd::Zero(m); for (int i = 0; i < m; i++) { if( C(i,0) < 0 ) signs(i) = -1; else signs(i) = 1; } C = signs.asDiagonal() * C; #ifdef DEBUG_JADE std::cout << "un mixing matrix" << std::endl; std::cout << C << std::endl; #endif // Unmix EX = C * EX; m_mixing_matrix = SGMatrix<float64_t>(m,m); Map<MatrixXd> Emixing_matrix(m_mixing_matrix.matrix,m,m); Emixing_matrix = C.inverse(); return features; }
bool HSpatialDivision2::divide(int target_count) { /* - variables - */ HSDVertexCluster2 vc; int i, lastClusterCount = 1, continuousUnchangeCount = 0; float diff; // maximum/minimum curvature and the direction float maxCurvature; // maximum curvature float minCurvature; // minimum curvature HNormal maxDir; // maximum curvature direction HNormal minDir; // maximum curvature direction SelfAdjointEigenSolver<Matrix3f> eigensolver; solver = &eigensolver; Matrix3f M; htime.setCheckPoint(); /* - routines - */ // init the first cluster for (i = 0; i < vertexCount; i ++) if (vertices[i].clusterIndex != INVALID_CLUSTER_INDEX) vc.addVertex(i, vertices[i]); cout << "\t-----------------------------------------------" << endl << "\tnon-referenced vertices count:\t" << vertexCount - vc.vIndices->size() << endl << "\tminimum normal-vari factor:\t" << HSDVertexCluster2::MINIMUM_NORMAL_VARI << endl << "\tvalid vertices count:\t" << vc.vIndices->size() << endl; flog << "\t-----------------------------------------------" << endl << "\tnon-referenced vertices count:\t" << vertexCount - vc.vIndices->size() << endl << "\tminimum normal-vari factor:\t" << HSDVertexCluster2::MINIMUM_NORMAL_VARI << endl << "\tvalid vertices count:\t" << vc.vIndices->size() << endl; for (i = 0; i < faceCount; i ++) { vc.addFace(i); } vc.importance = vc.getImportance(); clusters.addElement(vc); vector<int> index; // index of eigenvalues in eigensolver.eigenvalues() index.push_back(0); index.push_back(1); index.push_back(2); // subdivide until the divided clusters reach the target count while(clusters.count() < target_count) { //diff = ((float)target_count - (float)clusters.count()) / target_count; //if (diff < 0.01) { // break; //} if (clusters.count() == lastClusterCount) { continuousUnchangeCount ++; } else { continuousUnchangeCount = 0; } if (continuousUnchangeCount >= 50) { cout << "\tstop without reaching the target count because of unchanged cluster count" << endl; flog << "\tstop without reaching the target count because of unchanged cluster count" << endl; break; } if (clusters.empty()) { cerr << "#error: don't know why but the clusters heap have came to empty" << endl; flog << "#error: don't know why but the clusters heap have came to empty" << endl; return false; } // get the value of the top in the heap of clusters and delete it lastClusterCount = clusters.count(); vc = clusters.getTop(); clusters.deleteTop(); //PrintHeap(fout, clusters); // get the eigenvalue M << vc.awQ.a11, vc.awQ.a12, vc.awQ.a13, vc.awQ.a12, vc.awQ.a22, vc.awQ.a23, vc.awQ.a13, vc.awQ.a23, vc.awQ.a33; eigensolver.compute(M); if (eigensolver.info() != Success) { cerr << "#error: eigenvalues computing error" << endl; flog << "#error: eigenvalues computing error" << endl; return false; } // sort the eigenvalues in descending order by the index std::sort(index.begin(), index.end(), cmp); // get the maximum/minimum curvature and the direction maxCurvature = eigensolver.eigenvalues()(index[1]); // maximum curvature minCurvature = eigensolver.eigenvalues()(index[2]); // minimum curvature maxDir.Set(eigensolver.eigenvectors()(0, index[1]), eigensolver.eigenvectors()(1, index[1]), eigensolver.eigenvectors()(2, index[1])); // maximum curvature direction minDir.Set(eigensolver.eigenvectors()(0, index[2]), eigensolver.eigenvectors()(1, index[2]), eigensolver.eigenvectors()(2, index[2])); // maximum curvature direction // partition to 8 if (vc.awN.Length() / vc.area < SPHERE_MEAN_NORMAL_THRESH) { HNormal p_nm = maxDir ^ minDir; partition8(vc, p_nm, HFaceFormula::calcD(p_nm, vc.meanVertex), maxDir, HFaceFormula::calcD(maxDir, vc.meanVertex), minDir, HFaceFormula::calcD(minDir, vc.meanVertex)); } // partition to 4 else if (maxCurvature / minCurvature < MAX_MIN_CURVATURE_RATIO_TREATED_AS_HEMISPHERE) { partition4(vc, maxDir, HFaceFormula::calcD(maxDir, vc.meanVertex), minDir, HFaceFormula::calcD(minDir, vc.meanVertex)); } // partition to 2 else { partition2(vc, maxDir, HFaceFormula::calcD(maxDir, vc.meanVertex)); } #ifdef PRINT_DEBUG_INFO PrintHeap(fdebug, clusters); #endif } //PrintHeap(cout, clusters); cout << "\tsimplification time:\t" << htime.printElapseSec() << endl << endl; flog << "\tsimplification time:\t" << htime.printElapseSec() << endl << endl; return true; }
template<typename MatrixType> void selfadjointeigensolver(const MatrixType& m) { typedef typename MatrixType::Index Index; /* this test covers the following files: EigenSolver.h, SelfAdjointEigenSolver.h (and indirectly: Tridiagonalization.h) */ Index rows = m.rows(); Index cols = m.cols(); typedef typename MatrixType::Scalar Scalar; typedef typename NumTraits<Scalar>::Real RealScalar; RealScalar largerEps = 10*test_precision<RealScalar>(); MatrixType a = MatrixType::Random(rows,cols); MatrixType a1 = MatrixType::Random(rows,cols); MatrixType symmA = a.adjoint() * a + a1.adjoint() * a1; MatrixType symmC = symmA; // randomly nullify some rows/columns { Index count = 1;//internal::random<Index>(-cols,cols); for(Index k=0; k<count; ++k) { Index i = internal::random<Index>(0,cols-1); symmA.row(i).setZero(); symmA.col(i).setZero(); } } symmA.template triangularView<StrictlyUpper>().setZero(); symmC.template triangularView<StrictlyUpper>().setZero(); MatrixType b = MatrixType::Random(rows,cols); MatrixType b1 = MatrixType::Random(rows,cols); MatrixType symmB = b.adjoint() * b + b1.adjoint() * b1; symmB.template triangularView<StrictlyUpper>().setZero(); SelfAdjointEigenSolver<MatrixType> eiSymm(symmA); SelfAdjointEigenSolver<MatrixType> eiDirect; eiDirect.computeDirect(symmA); // generalized eigen pb GeneralizedSelfAdjointEigenSolver<MatrixType> eiSymmGen(symmC, symmB); VERIFY_IS_EQUAL(eiSymm.info(), Success); VERIFY((symmA.template selfadjointView<Lower>() * eiSymm.eigenvectors()).isApprox( eiSymm.eigenvectors() * eiSymm.eigenvalues().asDiagonal(), largerEps)); VERIFY_IS_APPROX(symmA.template selfadjointView<Lower>().eigenvalues(), eiSymm.eigenvalues()); VERIFY_IS_EQUAL(eiDirect.info(), Success); VERIFY((symmA.template selfadjointView<Lower>() * eiDirect.eigenvectors()).isApprox( eiDirect.eigenvectors() * eiDirect.eigenvalues().asDiagonal(), largerEps)); VERIFY_IS_APPROX(symmA.template selfadjointView<Lower>().eigenvalues(), eiDirect.eigenvalues()); SelfAdjointEigenSolver<MatrixType> eiSymmNoEivecs(symmA, false); VERIFY_IS_EQUAL(eiSymmNoEivecs.info(), Success); VERIFY_IS_APPROX(eiSymm.eigenvalues(), eiSymmNoEivecs.eigenvalues()); // generalized eigen problem Ax = lBx eiSymmGen.compute(symmC, symmB,Ax_lBx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmC.template selfadjointView<Lower>() * eiSymmGen.eigenvectors()).isApprox( symmB.template selfadjointView<Lower>() * (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); // generalized eigen problem BAx = lx eiSymmGen.compute(symmC, symmB,BAx_lx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmB.template selfadjointView<Lower>() * (symmC.template selfadjointView<Lower>() * eiSymmGen.eigenvectors())).isApprox( (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); // generalized eigen problem ABx = lx eiSymmGen.compute(symmC, symmB,ABx_lx); VERIFY_IS_EQUAL(eiSymmGen.info(), Success); VERIFY((symmC.template selfadjointView<Lower>() * (symmB.template selfadjointView<Lower>() * eiSymmGen.eigenvectors())).isApprox( (eiSymmGen.eigenvectors() * eiSymmGen.eigenvalues().asDiagonal()), largerEps)); eiSymm.compute(symmC); MatrixType sqrtSymmA = eiSymm.operatorSqrt(); VERIFY_IS_APPROX(MatrixType(symmC.template selfadjointView<Lower>()), sqrtSymmA*sqrtSymmA); VERIFY_IS_APPROX(sqrtSymmA, symmC.template selfadjointView<Lower>()*eiSymm.operatorInverseSqrt()); MatrixType id = MatrixType::Identity(rows, cols); VERIFY_IS_APPROX(id.template selfadjointView<Lower>().operatorNorm(), RealScalar(1)); SelfAdjointEigenSolver<MatrixType> eiSymmUninitialized; VERIFY_RAISES_ASSERT(eiSymmUninitialized.info()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvalues()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvectors()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorSqrt()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorInverseSqrt()); eiSymmUninitialized.compute(symmA, false); VERIFY_RAISES_ASSERT(eiSymmUninitialized.eigenvectors()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorSqrt()); VERIFY_RAISES_ASSERT(eiSymmUninitialized.operatorInverseSqrt()); // test Tridiagonalization's methods Tridiagonalization<MatrixType> tridiag(symmC); // FIXME tridiag.matrixQ().adjoint() does not work VERIFY_IS_APPROX(MatrixType(symmC.template selfadjointView<Lower>()), tridiag.matrixQ() * tridiag.matrixT().eval() * MatrixType(tridiag.matrixQ()).adjoint()); if (rows > 1) { // Test matrix with NaN symmC(0,0) = std::numeric_limits<typename MatrixType::RealScalar>::quiet_NaN(); SelfAdjointEigenSolver<MatrixType> eiSymmNaN(symmC); VERIFY_IS_EQUAL(eiSymmNaN.info(), NoConvergence); } }