Esempio n. 1
0
static bool check_trace(const Eigen::MatrixXcd& V, const int nb_ev){
  bool read_state = true;
  Eigen::MatrixXcd VdV(nb_ev,nb_ev);
  VdV = V.adjoint() * V;
  double eps = 10e-10;
  std::complex<double> trace (0.,0.), sum(0.,0.);
  trace = VdV.trace();
  sum = VdV.sum();
  std::cout << trace.real() << std::endl;
  if ( fabs( trace.real()) - nb_ev > eps ||
       fabs(trace.imag()) > eps ||
       fabs(sum.real()) - nb_ev > eps ||
       fabs(sum.imag()) > eps)
    read_state = false;
  return read_state; 
}
Esempio n. 2
0
int main() {
  const int dim_row = MAT_ENTRIES;
  const int dim_col = 120;// number of eigenvectors
  //Set up data structure
  Eigen::MatrixXcd V;
  Eigen::MatrixXcd V_dagger;
  Eigen::MatrixXcd S;
  V = Eigen::MatrixXcd::Zero( dim_row, dim_col);
  V_dagger = Eigen::MatrixXcd::Zero( dim_row, dim_col);
  S = Eigen::MatrixXcd::Zero( dim_row, dim_col);
  read_eigenvectors_from_binary_ts("eigenvectors", 600, 0, V);
  //read_eigenvectors_from_binary_ts("eigenvectors", 600, 0);
  std::cout << "Calculating v v_dagger" << std::endl;
  V_dagger = V.adjoint();
 
  for(int i = 0; i < dim_row; ++i ){
    for(int j = 0; j < dim_col; ++j) {
      //std::complex<double> entry =  V.row(i) * V_dagger.col(j);
      if (std::abs(V(i,j)) > 1e-15)  
      std::cout << i << " " << j << " " << V(i,j) << std::endl;
    }
  }
}