Exemplo n.º 1
0
def test_external_edge_identical_particle_combinatorics(
        initial_state, final_state, final_state_groupings, result_graph_count):
    tbd_manager = StateTransitionManager(initial_state,
                                         final_state, [],
                                         formalism_type="helicity")

    tbd_manager.set_allowed_interaction_types([InteractionTypes.Strong])
    for x in final_state_groupings:
        tbd_manager.add_final_state_grouping(x)
    tbd_manager.number_of_threads = 1

    topology_graphs = tbd_manager.build_topologies()

    init_graphs = tbd_manager.create_seed_graphs(topology_graphs)
    match_external_edges(init_graphs)

    comb_graphs = []
    for x in init_graphs:
        comb_graphs.extend(
            perform_external_edge_identical_particle_combinatorics(x))
    assert len(comb_graphs) == result_graph_count

    ref_mapping_fs = create_edge_id_particle_mapping(comb_graphs[0],
                                                     get_final_state_edges)
    ref_mapping_is = create_edge_id_particle_mapping(comb_graphs[0],
                                                     get_initial_state_edges)

    for x in comb_graphs[1:]:
        assert ref_mapping_fs == create_edge_id_particle_mapping(
            x, get_final_state_edges)
        assert ref_mapping_is == create_edge_id_particle_mapping(
            x, get_initial_state_edges)
Exemplo n.º 2
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def test_external_edge_identical_particle_combinatorics(initial_state,
                                                        final_state,
                                                        final_state_groupings,
                                                        result_graph_count):
    tbd_manager = StateTransitionManager(initial_state, final_state, [],
                                         formalism_type='helicity')

    tbd_manager.set_allowed_interaction_types([InteractionTypes.Strong])
    for x in final_state_groupings:
        tbd_manager.add_final_state_grouping(x)
    tbd_manager.number_of_threads = 1

    topology_graphs = tbd_manager.build_topologies()

    init_graphs = tbd_manager.create_seed_graphs(topology_graphs)
    match_external_edges(init_graphs)

    comb_graphs = []
    for x in init_graphs:
        comb_graphs.extend(
            perform_external_edge_identical_particle_combinatorics(x))
    assert len(comb_graphs) == result_graph_count

    ref_mapping_fs = create_edge_id_particle_mapping(comb_graphs[0],
                                                     get_final_state_edges)
    ref_mapping_is = create_edge_id_particle_mapping(comb_graphs[0],
                                                     get_initial_state_edges)

    for x in comb_graphs[1:]:
        assert ref_mapping_fs == create_edge_id_particle_mapping(
            x, get_final_state_edges)
        assert ref_mapping_is == create_edge_id_particle_mapping(
            x, get_initial_state_edges)
Exemplo n.º 3
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def test_external_edge_initialization(initial_state, final_state,
                                      final_state_groupings,
                                      result_graph_count):
    tbd_manager = StateTransitionManager(initial_state, final_state, [],
                                         formalism_type='helicity')

    tbd_manager.set_allowed_interaction_types([InteractionTypes.Strong])
    for x in final_state_groupings:
        tbd_manager.add_final_state_grouping(x)
    tbd_manager.number_of_threads = 1

    topology_graphs = tbd_manager.build_topologies()

    init_graphs = tbd_manager.create_seed_graphs(topology_graphs)
    assert len(init_graphs) == result_graph_count
Exemplo n.º 4
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def test_external_edge_initialization(initial_state, final_state,
                                      final_state_groupings,
                                      result_graph_count):
    tbd_manager = StateTransitionManager(initial_state, final_state, [],
                                         formalism_type='helicity')

    tbd_manager.set_allowed_interaction_types([InteractionTypes.Strong])
    for x in final_state_groupings:
        tbd_manager.add_final_state_grouping(x)
    tbd_manager.number_of_threads = 1

    topology_graphs = tbd_manager.build_topologies()

    init_graphs = tbd_manager.create_seed_graphs(topology_graphs)
    assert len(init_graphs) == result_graph_count
Exemplo n.º 5
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def main():
    logging.basicConfig(level=logging.INFO)

    # initialize the graph edges (initial and final state)
    initial_state = [("EpEm", [-1, 1])]
    final_state = [("Chic1", [-1, 1]), ("pi+", [0]), ("pi-", [0])]

    tbd_manager = StateTransitionManager(initial_state, final_state, [], {},
                                         "canonical")
    tbd_manager.add_final_state_grouping([["Chic1", "pi+"]])
    tbd_manager.set_allowed_interaction_types([InteractionTypes.EM])

    graph_node_setting_pairs = tbd_manager.prepare_graphs()
    (solutions,
     violated_rules) = tbd_manager.find_solutions(graph_node_setting_pairs)

    print("found " + str(len(solutions)) + " solutions!")
    if len(solutions) == 0:
        print("violated rules: " + str(violated_rules))

    print("intermediate states:")
    for g in solutions:
        print(g.edge_props[1]["@Name"])
Exemplo n.º 6
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from pycompwa.expertsystem.ui.system_control import (StateTransitionManager,
                                                     InteractionTypes)

from pycompwa.expertsystem.amplitude.helicitydecay import (
    HelicityDecayAmplitudeGeneratorXML)

logging.basicConfig(level=logging.INFO)

# initialize the graph edges (initial and final state)
initial_state = [("J/psi", [1])]
final_state = [("pi0", [0]), ("pi+", [0]), ("pi-", [0])]

tbd_manager = StateTransitionManager(initial_state, final_state, ['rho'])
# tbd_manager.number_of_threads = 1
tbd_manager.add_final_state_grouping(['pi+', 'pi-'])
tbd_manager.set_allowed_interaction_types([InteractionTypes.EM])
graph_interaction_settings_groups = tbd_manager.prepare_graphs()

(solutions, violated_rules
 ) = tbd_manager.find_solutions(graph_interaction_settings_groups)

print("found " + str(len(solutions)) + " solutions!")

print("intermediate states:")
for g in solutions:
    print(g.edge_props[1]['@Name'])

xml_generator = HelicityDecayAmplitudeGeneratorXML()
xml_generator.generate(solutions)
xml_generator.write_to_file('test.xml')
Exemplo n.º 7
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def test_script_full():
    # initialize the graph edges (intial and final state)
    initial_state = [("Y", [-1, 1])]
    final_state = ["D0", "D0bar", "pi0", "pi0"]

    # because the amount of solutions is too big we change the default domains
    formalism_type = 'canonical-helicity'
    int_settings = create_default_interaction_settings(formalism_type)
    change_qn_domain(int_settings[InteractionTypes.Strong],
                     InteractionQuantumNumberNames.L,
                     create_spin_domain([0, 1, 2, 3], True))
    change_qn_domain(int_settings[InteractionTypes.Strong],
                     InteractionQuantumNumberNames.S,
                     create_spin_domain([0, 1, 2], True))

    tbd_manager = StateTransitionManager(
        initial_state,
        final_state, ['D*'],
        interaction_type_settings=int_settings,
        formalism_type=formalism_type)

    tbd_manager.set_allowed_interaction_types([InteractionTypes.Strong])
    tbd_manager.add_final_state_grouping([['D0', 'pi0'], ['D0bar', 'pi0']])
    tbd_manager.number_of_threads = 2

    graph_node_setting_pairs = tbd_manager.prepare_graphs()

    (solutions,
     violated_rules) = tbd_manager.find_solutions(graph_node_setting_pairs)

    print("found " + str(len(solutions)) + " solutions!")

    canonical_xml_generator = CanonicalDecayAmplitudeGeneratorXML()
    canonical_xml_generator.generate(solutions)

    # because the amount of solutions is too big we change the default domains
    formalism_type = 'helicity'
    int_settings = create_default_interaction_settings(formalism_type)
    change_qn_domain(int_settings[InteractionTypes.Strong],
                     InteractionQuantumNumberNames.L,
                     create_spin_domain([0, 1, 2, 3], True))
    change_qn_domain(int_settings[InteractionTypes.Strong],
                     InteractionQuantumNumberNames.S,
                     create_spin_domain([0, 1, 2], True))

    tbd_manager = StateTransitionManager(
        initial_state,
        final_state, ['D*'],
        interaction_type_settings=int_settings,
        formalism_type=formalism_type)

    tbd_manager.set_allowed_interaction_types([InteractionTypes.Strong])
    tbd_manager.add_final_state_grouping([['D0', 'pi0'], ['D0bar', 'pi0']])
    tbd_manager.number_of_threads = 2

    graph_node_setting_pairs = tbd_manager.prepare_graphs()
    (solutions,
     violated_rules) = tbd_manager.find_solutions(graph_node_setting_pairs)
    print("found " + str(len(solutions)) + " solutions!")

    helicity_xml_generator = HelicityDecayAmplitudeGeneratorXML()
    helicity_xml_generator.generate(solutions)

    #print(helicity_xml_generator.fit_parameters,
    #      canonical_xml_generator.fit_parameters)
    assert (len(helicity_xml_generator.fit_parameters) == len(
        canonical_xml_generator.fit_parameters))
Exemplo n.º 8
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def test_script_full():
    # initialize the graph edges (intial and final state)
    initial_state = [("Y", [-1, 1])]
    final_state = ["D0", "D0bar", "pi0", "pi0"]

    # because the amount of solutions is too big we change the default domains
    formalism_type = 'canonical-helicity'
    int_settings = create_default_interaction_settings(formalism_type)
    change_qn_domain(int_settings[InteractionTypes.Strong],
                     InteractionQuantumNumberNames.L,
                     create_spin_domain([0, 1, 2, 3], True)
                     )
    change_qn_domain(int_settings[InteractionTypes.Strong],
                     InteractionQuantumNumberNames.S,
                     create_spin_domain([0, 1, 2], True)
                     )

    tbd_manager = StateTransitionManager(initial_state, final_state, ['D*'],
                                         interaction_type_settings=int_settings,
                                         formalism_type=formalism_type)

    tbd_manager.set_allowed_interaction_types([InteractionTypes.Strong])
    tbd_manager.add_final_state_grouping([['D0', 'pi0'], ['D0bar', 'pi0']])
    tbd_manager.number_of_threads = 2

    graph_node_setting_pairs = tbd_manager.prepare_graphs()

    (solutions, violated_rules) = tbd_manager.find_solutions(
        graph_node_setting_pairs)

    print("found " + str(len(solutions)) + " solutions!")

    canonical_xml_generator = CanonicalAmplitudeGeneratorXML()
    canonical_xml_generator.generate(solutions)

    # because the amount of solutions is too big we change the default domains
    formalism_type = 'helicity'
    int_settings = create_default_interaction_settings(formalism_type)
    change_qn_domain(int_settings[InteractionTypes.Strong],
                     InteractionQuantumNumberNames.L,
                     create_spin_domain([0, 1, 2, 3], True)
                     )
    change_qn_domain(int_settings[InteractionTypes.Strong],
                     InteractionQuantumNumberNames.S,
                     create_spin_domain([0, 1, 2], True)
                     )

    tbd_manager = StateTransitionManager(initial_state, final_state, ['D*'],
                                         interaction_type_settings=int_settings,
                                         formalism_type=formalism_type)

    tbd_manager.set_allowed_interaction_types([InteractionTypes.Strong])
    tbd_manager.add_final_state_grouping([['D0', 'pi0'], ['D0bar', 'pi0']])
    tbd_manager.number_of_threads = 2

    graph_node_setting_pairs = tbd_manager.prepare_graphs()
    (solutions, violated_rules) = tbd_manager.find_solutions(
        graph_node_setting_pairs)
    print("found " + str(len(solutions)) + " solutions!")

    helicity_xml_generator = HelicityAmplitudeGeneratorXML()
    helicity_xml_generator.generate(solutions)

    assert (len(helicity_xml_generator.get_fit_parameters()) ==
            len(canonical_xml_generator.get_fit_parameters()))
Exemplo n.º 9
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import logging

from pycompwa.expertsystem.ui.system_control import (
    StateTransitionManager, InteractionTypes)

logging.basicConfig(level=logging.INFO)

# initialize the graph edges (initial and final state)
initial_state = [("EpEm", [-1, 1])]
final_state = [("Chic1", [-1, 1]), ("pi+", [0]), ("pi-", [0])]

tbd_manager = StateTransitionManager(initial_state, final_state,
                                     [], {}, 'canonical')
tbd_manager.add_final_state_grouping([["Chic1", "pi+"]])
tbd_manager.set_allowed_interaction_types([InteractionTypes.EM])

graph_node_setting_pairs = tbd_manager.prepare_graphs()
(solutions, violated_rules) = tbd_manager.find_solutions(
    graph_node_setting_pairs)

print("found " + str(len(solutions)) + " solutions!")
if len(solutions) == 0:
    print("violated rules: " + str(violated_rules))

print("intermediate states:")
for g in solutions:
    print(g.edge_props[1]['@Name'])
Exemplo n.º 10
0
from pycompwa.expertsystem.ui.system_control import (
    StateTransitionManager, InteractionTypes)

from pycompwa.expertsystem.amplitude.helicitydecay import (
    HelicityDecayAmplitudeGeneratorXML)

logging.basicConfig(level=logging.INFO)

# initialize the graph edges (initial and final state)
initial_state = [("J/psi", [1])]
final_state = [("pi0", [0]), ("pi+", [0]), ("pi-", [0])]

tbd_manager = StateTransitionManager(initial_state, final_state,
                                     ['rho'])
#tbd_manager.number_of_threads = 1
tbd_manager.add_final_state_grouping(['pi+', 'pi-'])
tbd_manager.set_allowed_interaction_types(
    [InteractionTypes.EM])
graph_interaction_settings_groups = tbd_manager.prepare_graphs()

(solutions, violated_rules) = tbd_manager.find_solutions(
    graph_interaction_settings_groups)

print("found " + str(len(solutions)) + " solutions!")

print("intermediate states:")
for g in solutions:
    print(g.edge_props[1]['@Name'])

xml_generator = HelicityDecayAmplitudeGeneratorXML()
xml_generator.generate(solutions)