def initialize(self,evaluation_points): accuracy_options = _bempplib.createAccuracyOptions() accuracy_options.doubleRegular.setRelativeQuadratureOrder(self._relative_regular_quadrature_order) accuracy_options.doubleSingular.setRelativeQuadratureOrder(self._relative_singular_quadrature_order) accuracy_options.singleRegular.setRelativeQuadratureOrder(self._relative_regular_quadrature_order) assembly_options = _bempplib.createAssemblyOptions() assembly_options.setVerbosityLevel('low') if self._use_aca: aca_options = _bempplib.createAcaOptions() aca_options.maximumBlockSize = 2000 aca_options.maximumRank = 100 aca_options.eps = self._aca_epsilon assembly_options.switchToAca(aca_options) quad_strategy = _bempplib.createNumericalQuadratureStrategy("float64","complex128",accuracy_options) self._quad_strategy = quad_strategy self._context = _bempplib.createContext(quad_strategy,assembly_options) pconsts = _bempplib.createPiecewiseConstantScalarSpace(self._context,self._mesh) self._spaces = [pconsts,pconsts,pconsts] self._mass_matrix = _bempplib.createIdentityOperator(self._context,pconsts,pconsts,pconsts).weakForm() self._boundary_operator_cache = _tools.OperatorCache(self._operator_cache_tol) self._potential_operator_cache = _tools.OperatorCache(self._operator_cache_tol) self._residuals = {} self._evaluation_points = evaluation_points
def initialize_context(): accuracyOptions = lib.createAccuracyOptions() accuracyOptions.doubleRegular.setRelativeQuadratureOrder(2) accuracyOptions.doubleSingular.setRelativeQuadratureOrder(1) quadStrategy = lib.createNumericalQuadratureStrategy("float64","complex128",accuracyOptions) options = lib.createAssemblyOptions() options.setVerbosityLevel("low") aca_ops = lib.createAcaOptions() aca_ops.eps=1E-6 options.switchToAcaMode(aca_ops) context = lib.createContext(quadStrategy,options) return context
def initialize_context(): accuracyOptions = lib.createAccuracyOptions() accuracyOptions.doubleRegular.setRelativeQuadratureOrder(2) accuracyOptions.doubleSingular.setRelativeQuadratureOrder(1) quadStrategy = lib.createNumericalQuadratureStrategy( "float64", "complex128", accuracyOptions) options = lib.createAssemblyOptions() options.setVerbosityLevel("low") aca_ops = lib.createAcaOptions() aca_ops.eps = 1E-6 options.switchToAcaMode(aca_ops) context = lib.createContext(quadStrategy, options) return context
# use quadrature of 2 orders higher than default, and for singular # integrals, 1 order higher than default. accuracyOptions = lib.createAccuracyOptions() accuracyOptions.doubleRegular.setRelativeQuadratureOrder(2) accuracyOptions.doubleSingular.setRelativeQuadratureOrder(1) # The default strategy for numerical quadrature. # "float64" is the basis function type and "complex128" is the result type". quadStrategy = lib.createNumericalQuadratureStrategy( "float64", "complex128", accuracyOptions) # Use ACA to accelerate the assembly options = lib.createAssemblyOptions() options.switchToAca(lib.createAcaOptions()) # The context object combines these settings context = lib.createContext(quadStrategy, options) # Load a grid approximating a unit sphere grid_factory = lib.createGridFactory() grid = grid_factory.importGmshGrid( "triangular", "../../meshes/sphere-h-0.1.msh") # Create a space of piecewise constant basis functions over the grid. pwiseConstants = lib.createPiecewiseConstantScalarSpace(context, grid)
os.remove(s2_geo_name) os.remove(s3_geo_name) os.remove(s1_msh_name) os.remove(s2_msh_name) os.remove(s3_msh_name) # Create Context accuracy_options = blib.createAccuracyOptions() accuracy_options.doubleRegular.setRelativeQuadratureOrder( 2) # 2 orders higher than default accuracy for regular integrals accuracy_options.doubleSingular.setRelativeQuadratureOrder( 1) # 1 order higher than default accuracy for singular integrals strategy = blib.createNumericalQuadratureStrategy("float64", "complex128", accuracy_options) options = blib.createAssemblyOptions() aca_options = blib.createAcaOptions() aca_options.eps = 1E-5 options.switchToAca(aca_options) context = blib.createContext(strategy, options) # Create the spaces sphere1_plc = blib.createPiecewiseLinearContinuousScalarSpace(context, sphere1) sphere2_plc = blib.createPiecewiseLinearContinuousScalarSpace(context, sphere2) sphere3_plc = blib.createPiecewiseLinearContinuousScalarSpace(context, sphere3) # Now create the operators slp11 = blib.createModifiedHelmholtz3dSingleLayerBoundaryOperator( context, sphere1_plc, sphere1_plc, sphere1_plc, w1) dlp11 = blib.createModifiedHelmholtz3dDoubleLayerBoundaryOperator(
def create_bempp_options(solver_use_aca = True, evaluation_use_aca = True, solver_aca_epsilon = 1E-6, solver_aca_maximum_rank = 200, solver_aca_maximum_block_size = 2000, solver_aca_mode = 'hybrid_assembly', solver_aca_eta = 1.2, evaluation_aca_epsilon = 1E-3, evaluation_aca_eta = 0.4, evaluation_aca_maximum_rank = 30, evaluation_aca_maximum_block_size = 2000, evaluation_aca_mode = 'global_assembly', relative_double_singular_quadrature_order = 2, relative_double_regular_quadrature_order = 1, relative_single_regular_quadrature_order = 1, verbosity_level = 'low', basis_function_type = 'float64', result_type = 'complex128', number_of_threads = None ): solver_assembly_options = _bempplib.createAssemblyOptions() if number_of_threads is not None: solver_assembly_options.setMaxThreadCount(number_of_threads) solver_assembly_options.setVerbosityLevel(verbosity_level) if solver_use_aca: solver_aca_options = _bempplib.createAcaOptions() solver_aca_options.mode = solver_aca_mode solver_aca_options.eps = solver_aca_epsilon solver_aca_options.eta = solver_aca_eta solver_aca_options.maximumBlockSize = solver_aca_maximum_block_size solver_aca_options.maximumRank = solver_aca_maximum_rank solver_assembly_options.switchToAca(solver_aca_options) solver_accuracy_options = _bempplib.createAccuracyOptions() solver_accuracy_options.doubleRegular.setRelativeQuadratureOrder(relative_double_regular_quadrature_order) solver_accuracy_options.doubleSingular.setRelativeQuadratureOrder(relative_double_singular_quadrature_order) quadrature_strategy = _bempplib.createNumericalQuadratureStrategy(basis_function_type,result_type,solver_accuracy_options) context = _bempplib.createContext(quadrature_strategy,solver_assembly_options) evaluation_options = _bempplib.createEvaluationOptions() evaluation_accuracy_options = _bempplib.createAccuracyOptions() evaluation_accuracy_options.singleRegular.setRelativeQuadratureOrder(relative_single_regular_quadrature_order) evaluation_quadrature_strategy = _bempplib.createNumericalQuadratureStrategy(basis_function_type,result_type,evaluation_accuracy_options) if evaluation_use_aca: evaluation_aca_options = _bempplib.createAcaOptions() evaluation_aca_options.eps = evaluation_aca_epsilon evaluation_aca_options.eta = evaluation_aca_eta evaluation_aca_options.mode = evaluation_aca_mode evaluation_aca_options.maximumBlockSize = evaluation_aca_maximum_block_size evaluation_aca_options.maximumRank = evaluation_aca_maximum_rank evaluation_options.switchToAcaMode(evaluation_aca_options) return (context,evaluation_options,evaluation_quadrature_strategy)