void find_boundary_component_germs(GRID const& G, FACETSET & C,
int& num_comps, int& num_facets)
{
typedef GRID grid_type;
typedef grid_types<GRID> gt;
typedef typename gt::Facet Facet;
typedef typename gt::FacetIterator FacetIterator;
typedef iscellinside_pred<grid_type> inside;
typedef BoundaryComponentEdgeIterator2D<grid_type, inside> BCFacetIterator;
partial_grid_function<Facet,bool> marked(G,false);
num_comps = num_facets = 0;
for(FacetIterator f = G.FirstFacet(); ! f.IsDone(); ++f)
if( (! marked(*f)) && (G.IsOnBoundary(*f))) {
C.push_back(*f);
num_comps++;
BCFacetIterator bf(*f,inside(G));
while(! bf.IsDone()) {
num_facets++;
marked[*bf] = true;
++bf;
}
}
}
int count_boundary_facets(GRID const& G)
{
typedef GRID grid_type;
typedef grid_types<GRID> gt;
typedef typename gt::FacetIterator FacetIterator;
int nf = 0;
for(FacetIterator f = G.FirstFacet(); ! f.IsDone(); ++f)
if(G.IsOnBoundary(*f))
++nf;
return nf;
}
void setup(SegmentT const & segment, StorageType & storage)
{
typedef typename SegmentT::config_type config_type;
typedef viennamath::equation equ_type;
typedef viennamath::expr expr_type;
typedef typename expr_type::numeric_type numeric_type;
typedef typename viennagrid::result_of::cell_tag<SegmentT>::type CellTag;
typedef typename viennagrid::result_of::facet_tag<CellTag>::type FacetTag;
typedef typename viennagrid::result_of::point<SegmentT>::type PointType;
typedef typename viennagrid::result_of::element<SegmentT, FacetTag>::type FacetType;
typedef typename viennagrid::result_of::element<SegmentT, CellTag >::type CellType;
typedef typename viennagrid::result_of::const_element_range<SegmentT, FacetTag>::type FacetContainer;
typedef typename viennagrid::result_of::iterator<FacetContainer>::type FacetIterator;
typedef typename viennagrid::result_of::const_coboundary_range<SegmentT, FacetType, CellTag>::type CellOnFacetRange;
// typedef typename viennagrid::result_of::const_element_range<FacetType, CellTag>::type CellOnFacetRange;
typedef typename viennagrid::result_of::iterator<CellOnFacetRange>::type CellOnFacetIterator;
typename viennadata::result_of::accessor<StorageType, viennafvm::facet_area_key, double, FacetType>::type facet_area_accessor =
viennadata::make_accessor(storage, viennafvm::facet_area_key());
typename viennadata::result_of::accessor<StorageType, viennafvm::facet_distance_key, double, FacetType>::type facet_distance_accessor =
viennadata::make_accessor(storage, viennafvm::facet_distance_key());
FacetContainer facets(segment);
for (FacetIterator fit = facets.begin();
fit != facets.end();
++fit)
{
CellOnFacetRange cells = viennagrid::coboundary_elements<FacetType, CellTag>(segment, fit.handle());
if (cells.size() == 2)
{
CellOnFacetIterator cofit = cells.begin();
PointType centroid_1 = viennagrid::centroid(*cofit); ++cofit;
PointType centroid_2 = viennagrid::centroid(*cofit);
PointType center_connection = centroid_1 - centroid_2;
PointType outer_normal = util::unit_outer_normal(*fit, *cofit, viennagrid::default_point_accessor(segment)); //note: consistent orientation of center_connection and outer_normal is important here!
double center_connection_len = viennagrid::norm(center_connection);
double effective_facet_ratio = viennagrid::inner_prod(center_connection, outer_normal) / center_connection_len; // inner product of unit vectors
double effective_facet_area = viennagrid::volume(*fit) * effective_facet_ratio;
facet_area_accessor(*fit) = effective_facet_area;
facet_distance_accessor(*fit) = center_connection_len;
}
}
}
static void detect(AccessorT accessor,
MeshT1 const & seg0,
MeshT2 const & seg1)
{
typedef typename viennagrid::result_of::cell_tag<MeshT1>::type CellTag;
typedef typename viennagrid::result_of::element<MeshT1, typename CellTag::facet_tag>::type FacetType;
typedef typename viennagrid::result_of::const_handle<MeshT1, typename CellTag::facet_tag>::type ConstFacetHandleType;
typedef typename viennagrid::result_of::const_element_range<MeshT1, typename CellTag::facet_tag>::type FacetRange;
typedef typename viennagrid::result_of::iterator<FacetRange>::type FacetIterator;
std::set<ConstFacetHandleType> facets_ptrs_seg0;
//
// Step 1: Write facets of segment 1 to a map:
//
FacetRange facets_seg0(seg0);
for (FacetIterator fit = facets_seg0.begin();
fit != facets_seg0.end();
++fit)
{
const FacetType & facet = *fit;
if (is_boundary(seg0, facet))
facets_ptrs_seg0.insert( fit.handle() );
}
//
// Step 2: Compare facet in segment 2 with those stored in the map
//
FacetRange facets_seg1(seg1);
for (FacetIterator fit = facets_seg1.begin();
fit != facets_seg1.end();
++fit)
{
const FacetType & facet = *fit;
if (facets_ptrs_seg0.find( fit.handle() ) != facets_ptrs_seg0.end()) accessor(facet) = true;
}
}
void assemble( DeviceType & device,
TimeStepQuantitiesT & old_quantities,
TimeStepQuantitiesT & quantities,
viennashe::config const & conf,
viennashe::she::unknown_she_quantity<VertexT, EdgeT> const & quan,
MatrixType & A,
VectorType & b,
bool use_timedependence, bool quan_valid)
{
typedef typename DeviceType::mesh_type MeshType;
typedef typename viennagrid::result_of::facet<MeshType>::type FacetType;
typedef typename viennagrid::result_of::cell<MeshType>::type CellType;
typedef typename viennagrid::result_of::const_facet_range<MeshType>::type FacetContainer;
typedef typename viennagrid::result_of::iterator<FacetContainer>::type FacetIterator;
typedef typename viennagrid::result_of::const_cell_range<MeshType>::type CellContainer;
typedef typename viennagrid::result_of::iterator<CellContainer>::type CellIterator;
typedef typename viennagrid::result_of::const_facet_range<CellType>::type FacetOnCellContainer;
typedef typename viennagrid::result_of::iterator<FacetOnCellContainer>::type FacetOnCellIterator;
typedef typename viennagrid::result_of::const_coboundary_range<MeshType, FacetType, CellType>::type CellOnFacetContainer;
typedef typename viennagrid::result_of::iterator<CellOnFacetContainer>::type CellOnFacetIterator;
typedef viennashe::math::sparse_matrix<double> CouplingMatrixType;
typedef typename viennashe::she::timestep_quantities<DeviceType>::unknown_quantity_type SpatialUnknownType;
std::vector< scattering_base<DeviceType> * > scattering_processes;
if (conf.with_traps())
{
if (! conf.with_electrons() || ! conf.with_holes())
throw viennashe::unavailable_feature_exception("Trapping without considering electrons or holes is not supported!");
if ( conf.get_electron_equation() != viennashe::EQUATION_SHE)
throw viennashe::unavailable_feature_exception("Trapping without SHE for electrons is not supported!");
if ( conf.get_hole_equation() != viennashe::EQUATION_SHE)
throw viennashe::unavailable_feature_exception("Trapping without SHE for holes is not supported!");
}
// try
// {
MeshType const & mesh = device.mesh();
SpatialUnknownType const & potential = quantities.get_unknown_quantity(viennashe::quantity::potential());
SpatialUnknownType const & old_potential = old_quantities.get_unknown_quantity(viennashe::quantity::potential()); //TODO: Take old timestep
viennashe::she::unknown_she_quantity<VertexT, EdgeT> const & old_quan = old_quantities.she_quantity(quan.get_name());
//
// Set up scatter matrices:
//
const std::size_t L_max = static_cast<std::size_t>(conf.max_expansion_order());
const std::size_t num_harmonics = std::size_t(L_max+1) * std::size_t(L_max+1);
CouplingMatrixType scatter_op_in(num_harmonics, num_harmonics);
CouplingMatrixType scatter_op_out(num_harmonics, num_harmonics);
for (std::size_t i=0; i < std::size_t(L_max+1) * std::size_t(L_max+1); ++i)
scatter_op_out(i,i) += 1.0;
scatter_op_in(0,0) += 1.0;
//// preprocessing: compute coefficients a_{l,m}^{l',m'} and b_{l,m}^{l',m'}
std::size_t Lmax = static_cast<std::size_t>(conf.max_expansion_order()); //maximum expansion order
std::size_t coupling_rows = static_cast<std::size_t>((Lmax+1) * (Lmax+1));
std::size_t coupling_cols = coupling_rows;
log::debug<log_assemble_all>() << "* assemble_all(): Computing coupling matrices..." << std::endl;
CouplingMatrixType identity(coupling_rows, coupling_cols);
for (std::size_t i=0; i<coupling_rows; ++i)
for (std::size_t j=0; j<coupling_cols; ++j)
identity(i,j) = (i == j) ? 1.0 : 0.0;
CouplingMatrixType a_x(coupling_rows, coupling_cols);
CouplingMatrixType a_y(coupling_rows, coupling_cols);
CouplingMatrixType a_z(coupling_rows, coupling_cols);
CouplingMatrixType b_x(coupling_rows, coupling_cols);
CouplingMatrixType b_y(coupling_rows, coupling_cols);
CouplingMatrixType b_z(coupling_rows, coupling_cols);
//note: interchanged coordinates
fill_coupling_matrices(a_x, a_y, a_z,
b_x, b_y, b_z,
static_cast<int>(Lmax));
CouplingMatrixType a_x_transposed = a_x.trans();
CouplingMatrixType a_y_transposed = a_y.trans();
CouplingMatrixType a_z_transposed = a_z.trans();
CouplingMatrixType b_x_transposed = b_x.trans();
CouplingMatrixType b_y_transposed = b_y.trans();
CouplingMatrixType b_z_transposed = b_z.trans();
if (log_assemble_all::enabled && log_assemble_all::debug)
{
log::debug<log_assemble_all>() << "a_x: " << a_x << std::endl;
log::debug<log_assemble_all>() << "a_y: " << a_y << std::endl;
log::debug<log_assemble_all>() << "a_z: " << a_z << std::endl;
log::debug<log_assemble_all>() << "b_x: " << b_x << std::endl;
log::debug<log_assemble_all>() << "b_y: " << b_y << std::endl;
log::debug<log_assemble_all>() << "b_z: " << b_z << std::endl;
log::debug<log_assemble_all>() << "identity: " << identity << std::endl;
log::debug<log_assemble_all>() << "scatter_op_out: " << scatter_op_out << std::endl;
log::debug<log_assemble_all>() << "scatter_op_in: " << scatter_op_in << std::endl;
}
//
// Setup vector of scattering processes:
//
if (conf.scattering().acoustic_phonon().enabled())
{
log::debug<log_assemble_all>() << "assemble(): Acoustic phonon scattering is ENABLED!" << std::endl;
scattering_processes.push_back(new acoustic_phonon_scattering<DeviceType>(device, conf));
}
if (conf.scattering().optical_phonon().enabled())
{
log::debug<log_assemble_all>() << "assemble(): Optical phonon scattering is ENABLED!" << std::endl;
scattering_processes.push_back(new optical_phonon_scattering<DeviceType>(device, conf, conf.energy_spacing()));
}
if (conf.scattering().ionized_impurity().enabled())
{
log::debug<log_assemble_all>() << "assemble(): Ionized impurity scattering is ENABLED!" << std::endl;
scattering_processes.push_back(new ionized_impurity_scattering<DeviceType>(device, conf));
}
if (conf.scattering().impact_ionization().enabled())
{
// Warn the user if we already know that he/she is going to simulate bullshit.
if ( ! conf.with_holes() || conf.get_hole_equation() != viennashe::EQUATION_SHE )
log::warn() << std::endl << "WARNING: II scattering enabled, but 'BTE for holes' is disabled! Expect inconsistent results!" << std::endl;
if ( ! conf.with_electrons() || conf.get_electron_equation() != viennashe::EQUATION_SHE )
log::warn() << std::endl << "WARNING: II scattering enabled, but 'BTE for electrons' is disabled! Expect inconsistent results!" << std::endl;
scattering_processes.push_back(new impact_ionization_scattering<DeviceType>(device, conf));
}
if (conf.with_traps() && conf.scattering().trapped_charge().enabled())
{
log::debug<log_assemble_all>() << "assemble(): Trapped charge scattering is ENABLED!" << std::endl;
scattering_processes.push_back(new trapped_charge_scattering<DeviceType, TimeStepQuantitiesT>(device, conf, quantities));
}
typedef typename viennashe::electric_field_wrapper<DeviceType, SpatialUnknownType> ElectricFieldAccessor;
ElectricFieldAccessor Efield(device, potential);
if (conf.scattering().surface().enabled())
{
log::debug<log_assemble_all>() << "assemble(): Surface roughness scattering is ENABLED!" << std::endl;
scattering_processes.push_back(new surface_scattering<DeviceType, ElectricFieldAccessor>(device, conf, Efield));
}
//
// Assemble SHE system:
// - scattering operators on vertices
// - free streaming operator on vertices
// - scattering operators on edges
// - free streaming operator on edges
// - any other stuff (traps on cells, etc.)
//
if (quan_valid && conf.scattering().electron_electron() && conf.with_electrons())
{
log::debug<log_assemble_all>() << "assemble(): Electron electron scattering is ENABLED!" << std::endl;
assemble_ee_scattering(device, conf, quan, old_quan, A, b);
}
//
// Step 1: Assemble on even nodes
//
log::debug<log_assemble_all>() << "* assemble_all(): Even unknowns..." << std::endl;
CellContainer cells(mesh);
for (CellIterator cit = cells.begin();
cit != cells.end();
++cit)
{
log::debug<log_assemble_all>() << "* assemble_all(): Assembling on cell " << *cit << std::endl;
for (std::size_t index_H = 0; index_H < quan.get_value_H_size(); ++index_H)
{
if (log_assemble_all::enabled)
log::debug<log_assemble_all>() << "* assemble_all(): Assembling on energy index " << index_H << std::endl;
assemble_boundary_on_box(device, conf, quan,
A, b,
*cit, index_H,
identity);
if (viennashe::materials::is_conductor(device.get_material(*cit)))
continue;
//
// Scattering operator Q{f}
//
assemble_scattering_operator_on_box( scattering_processes,
device, conf, quan,
A, b,
*cit, index_H,
scatter_op_in, scatter_op_out);
}
//
// Free streaming operator L{f}
//
// iterate over neighbor cells holding the odd unknowns:
FacetOnCellContainer facets_on_cell(*cit);
for (FacetOnCellIterator focit = facets_on_cell.begin();
focit != facets_on_cell.end();
++focit)
{
if (log_assemble_all::enabled)
log::debug<log_assemble_all>() << "* assemble_all(): Assembling coupling with facet " << *focit << std::endl;
CellType const *other_cell_ptr = util::get_other_cell_of_facet(mesh, *focit, *cit);
if (!other_cell_ptr) continue; //Facet is on the boundary of the simulation domain -> homogeneous Neumann conditions
CouplingMatrixType coupling_matrix_diffusion = coupling_matrix_in_direction(a_x, a_y, a_z,
*cit,
*other_cell_ptr,
quan.get_carrier_type_id());
// note that the sign change due to MEDS is included in the choice of the normal vector direction (order of vertex vs. other_vertex):
// - B \cdot n for even unknowns,
// + B \cdot n for odd unknowns
CouplingMatrixType coupling_matrix_drift = coupling_matrix_in_direction(b_x, b_y, b_z, *other_cell_ptr, *cit, quan.get_carrier_type_id());
for (std::size_t index_H = 0; index_H < quan.get_value_H_size(); ++index_H)
{
assemble_free_streaming_operator_on_box( device, conf, quan,
A, b,
*cit, *focit, index_H,
coupling_matrix_diffusion,
coupling_matrix_drift,
false);
}
} //for edges
//
// Time dependence df/dt (and possibly df/dH * dH/dt)
//
if (use_timedependence)
{
for (std::size_t index_H = 0; index_H < quan.get_value_H_size(); ++index_H)
{
viennashe::she::assemble_timederivative(device, conf, quan, old_quan,
A, b,
*cit, index_H,
identity,
potential,
old_potential);
}
}
} //for cells
//
// Step 2: Assemble on odd 'nodes' (i.e. facets). TODO: Resolve code duplication w.r.t. above
//
log::info<log_assemble_all>() << "* assemble_all(): Odd unknowns..." << std::endl;
FacetContainer facets(mesh);
for (FacetIterator fit = facets.begin();
fit != facets.end();
++fit)
{
if (log_assemble_all::enabled)
log::debug<log_assemble_all>() << "* assemble_all(): Assembling on facet " << *fit << std::endl;
for (std::size_t index_H = 0; index_H < quan.get_value_H_size(); ++index_H)
{
if (log_assemble_all::enabled)
log::debug<log_assemble_all>() << "* assemble_all(): Assembling on energy index " << index_H << std::endl;
//
// Scattering operator Q{f}
//
assemble_scattering_operator_on_box(scattering_processes,
device, conf, quan,
A, b,
*fit, index_H,
scatter_op_in, scatter_op_out);
}
//
// Free streaming operator L{f}
//
// iterate over cells of facet
CellOnFacetContainer cells_on_facet(mesh, fit.handle());
for (CellOnFacetIterator cofit = cells_on_facet.begin();
cofit != cells_on_facet.end();
++cofit)
{
if (log_assemble_all::enabled)
log::debug<log_assemble_all>() << "* assemble_all(): Assembling coupling with cell " << *cofit << std::endl;
CellType const *other_cell_ptr = util::get_other_cell_of_facet(mesh, *fit, *cofit);
if (!other_cell_ptr) continue; //Facet is on the boundary of the simulation domain -> homogeneous Neumann conditions
CouplingMatrixType coupling_matrix_diffusion = coupling_matrix_in_direction(a_x_transposed, a_y_transposed, a_z_transposed,
*other_cell_ptr,
*cofit,
quan.get_carrier_type_id());
// note that the sign change due to MEDS is included in the choice of the normal vector direction (order of vertex vs. other_vertex):
// - B \cdot n for even unknowns,
// + B \cdot n for odd unknowns
CouplingMatrixType coupling_matrix_drift = coupling_matrix_in_direction(b_x_transposed, b_y_transposed, b_z_transposed, *other_cell_ptr, *cofit, quan.get_carrier_type_id());
for (std::size_t index_H = 0; index_H < quan.get_value_H_size(); ++index_H)
{
assemble_free_streaming_operator_on_box( device, conf, quan,
A, b,
*cofit, *fit, index_H,
coupling_matrix_diffusion,
coupling_matrix_drift,
true);
}
} //for vertices
//
// Time dependence df/dt (and possibly df/dH * dH/dt)
//
if (use_timedependence)
{
for (std::size_t index_H = 0; index_H < quan.get_value_H_size(); ++index_H)
{
viennashe::she::assemble_timederivative(device, conf, quan, old_quan,
A, b,
*fit, index_H,
identity,
potential,
old_potential);
}
}
} //for facets
// Assemble traps on cells (to be integrated into the assembly above):
if (conf.with_traps())
{
log::debug<log_assemble_all>() << "assemble(): Assembly for traps ..." << std::endl;
viennashe::she::assemble_traps(device, quantities, conf, quan, A, b);
}
//
// Cleanup:
//
for (std::size_t i=0; i<scattering_processes.size(); ++i)
{
if ( scattering_processes[i] ) delete scattering_processes[i];
scattering_processes[i] = 0;
}
/* }
catch (...)
{
//
// Cleanup:
//
for (std::size_t i=0; i<scattering_processes.size(); ++i)
if ( scattering_processes[i] ) delete scattering_processes[i];
// Rethrow
throw;
}
*/
}
