Esempio n. 1
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def CreateSolution(device, region, name):
    """
        Creates solution variables
        As well as their entries on each edge
    """
    node_solution(name=name, device=device, region=region)
    edge_from_node_model(node_model=name, device=device, region=region)
Esempio n. 2
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 def create_solution(self, region, name):
     '''
     Creates solution variables
     As well as their entries on each edge
     '''
     node_solution(name=name, device=self.name, region=region)
     edge_from_node_model(node_model=name, device=self.name, region=region)
Esempio n. 3
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 def create_solution_variable(self, name):
     """
     Creates solution variables
     As well as their entries on each edge
     """
     for region in self.mesh.regions:
         node_solution(name=name, device=self.name, region=region)
         edge_from_node_model(node_model=name,
                              device=self.name,
                              region=region)
Esempio n. 4
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def create_solution(device=None, regions=None, name=None):
    """
    Creates a variable to be solved during the simulation
    Also creates the edge models for the node solution so you have access on edges and nodes
    :param device:
    :param region:
    :param name:
    :return:
    """
    if device is None:
        device = ds.get_device_list()[0]
    if regions is None:
        regions = ds.get_region_list(device=device)
    if type(regions) is str:
        regions = [regions]
    try:
        regions[0]
    except IndexError:
        regions = [regions]
    for region in regions:
        ds.node_solution(name=name, device=device, region=region)
        ds.edge_from_node_model(node_model=name, device=device, region=region)
Esempio n. 5
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def create_solution(device, region, name):
    ds.node_solution(name=name, device=device, region=region)
    ds.edge_from_node_model(node_model=name, device=device, region=region)
Esempio n. 6
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set_parameter(device=device, region=region, name="taun", value=1e-8)
set_parameter(device=device, region=region, name="taup", value=1e-8)

# SetNetDoping(device=device, region=region)
CreateNodeModel(device, region, "Acceptors", "1.0e18*step(0.5e-5-x)")
CreateNodeModel(device, region, "Donors", "1.0e18*step(x-0.5e-5)")
CreateNodeModel(device, region, "NetDoping", "Donors-Acceptors")

print_node_values(device=device, region=region, name="NetDoping")

# InitialSolution(device, region)
circuit_contacts = None
# Create Potential, Potential@n0, Potential@n1
# CreateSolution(device, region, "Potential")
name = "Potential"
node_solution(name=name, device=device, region=region)
edge_from_node_model(node_model=name, device=device, region=region)

# Create potential only physical models
CreateSiliconPotentialOnly(device, region)

# Set up the contacts applying a bias
for i in get_contact_list(device=device):
    if circuit_contacts and i in circuit_contacts:
        CreateSiliconPotentialOnlyContact(device, region, i, True)
    else:
        ###print "FIX THIS"
        ### it is more correct for the bias to be 0, and it looks like there is side effects
        set_parameter(device=device, name=GetContactBiasName(i), value=0.0)
        CreateSiliconPotentialOnlyContact(device, region, i)
Esempio n. 7
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    def setup_drift_diffusion(self,
                              dielectric_const=11.9,
                              intrinsic_carriers=1E10,
                              work_function=4.05,
                              band_gap=1.124,
                              Ncond=3E19,
                              Nval=3E19,
                              mobility_n=1107,
                              mobility_p=424.6,
                              Nacceptors=0,
                              Ndonors=0):
        """
        Sets up equations for a drift-diffusion style of dc current transport.

        kwargs here are device-level parameters, imbuing all regions with these properties
        If a specific region or material is to have a different set of parameters, they can be set through the
        Region constructor.
        :param dielectric_const:
        :param intrinsic_carriers:
        :param work_function:
        :param band_gap:
        :param Ncond:
        :param Nval:
        :param mobility_n:
        :param mobility_p:
        :param Nacceptors:
        :param Ndonors:
        :return:
        """
        # Begin legacy copy-paste job
        # Set silicon parameters
        device = self.name
        region = self.regions[0].name
        eps_si = dielectric_const
        n_i = 1E10
        k = kb
        mu_n = mobility_n
        mu_p = mobility_p
        set_parameter(device=device,
                      region=region,
                      name="Permittivity",
                      value=eps_si * eps_0)
        set_parameter(device=device,
                      region=region,
                      name="ElectronCharge",
                      value=q)
        set_parameter(device=device, region=region, name="n_i", value=n_i)
        set_parameter(device=device, region=region, name="T", value=T)
        set_parameter(device=device, region=region, name="kT", value=k * T)
        set_parameter(device=device,
                      region=region,
                      name="V_t",
                      value=k * T / q)
        set_parameter(device=device, region=region, name="mu_n", value=mu_n)
        set_parameter(device=device, region=region, name="mu_p", value=mu_p)
        # default SRH parameters
        set_parameter(device=device, region=region, name="n1", value=n_i)
        set_parameter(device=device, region=region, name="p1", value=n_i)
        set_parameter(device=device, region=region, name="taun", value=1e-5)
        set_parameter(device=device, region=region, name="taup", value=1e-5)
        # CreateNodeModel 3 times
        for name, value in [('Acceptors', "1.0e18*step(0.5e-5-x)"),
                            ('Donors', "1.0e18*step(x-0.5e-5)"),
                            ('NetDoping', "Donors-Acceptors")]:
            result = node_model(device=device,
                                region=region,
                                name=name,
                                equation=value)
            logger.debug(f"NODEMODEL {device} {region} {name} '{result}'")
        print_node_values(device=device, region=region, name="NetDoping")
        model_name = "Potential"
        node_solution(name=model_name, device=device, region=region)
        edge_from_node_model(node_model=model_name,
                             device=device,
                             region=region)
        # Create silicon potentialOnly
        if model_name not in get_node_model_list(device=device, region=region):
            logger.debug("Creating Node Solution Potential")
            node_solution(device=device, region=region, name=model_name)
            edge_from_node_model(node_model=model_name,
                                 device=device,
                                 region=region)

        # require NetDoping
        for name, eq in (
            ("IntrinsicElectrons", "n_i*exp(Potential/V_t)"),
            ("IntrinsicHoles", "n_i^2/IntrinsicElectrons"),
            ("IntrinsicCharge",
             "kahan3(IntrinsicHoles, -IntrinsicElectrons, NetDoping)"),
            ("PotentialIntrinsicCharge", "-ElectronCharge * IntrinsicCharge")):
            node_model(device=device, region=region, name=name, equation=eq)
            node_model(device=device,
                       region=region,
                       name=f"{name}:{model_name}",
                       equation=f"simplify(diff({eq},{model_name}))")
            # CreateNodeModelDerivative(device, region, name, eq, model_name)

        ### TODO: Edge Average Model
        for name, eq in (("ElectricField",
                          "(Potential@n0-Potential@n1)*EdgeInverseLength"),
                         ("PotentialEdgeFlux",
                          "Permittivity * ElectricField")):
            edge_model(device=device, region=region, name=name, equation=eq)
            edge_model(device=device,
                       region=region,
                       name=f"{name}:{model_name}@n0",
                       equation=f"simplify(diff({eq}, {model_name}@n0))")
            edge_model(device=device,
                       region=region,
                       name=f"{name}:{model_name}@n1",
                       equation=f"simplify(diff({eq}, {model_name}@n1))")

        equation(device=device,
                 region=region,
                 name="PotentialEquation",
                 variable_name=model_name,
                 node_model="PotentialIntrinsicCharge",
                 edge_model="PotentialEdgeFlux",
                 variable_update="log_damp")

        # Set up the contacts applying a bias
        is_circuit = False
        for contact_name in get_contact_list(device=device):
            set_parameter(device=device,
                          name=f"{contact_name}_bias",
                          value=0.0)
            # CreateSiliconPotentialOnlyContact(device, region, contact_name)
            # Start
            # Means of determining contact charge
            # Same for all contacts
            if not InNodeModelList(device, region, "contactcharge_node"):
                create_node_model(device, region, "contactcharge_node",
                                  "ElectronCharge*IntrinsicCharge")
            #### TODO: This is the same as D-Field
            if not InEdgeModelList(device, region, "contactcharge_edge"):
                CreateEdgeModel(device, region, "contactcharge_edge",
                                "Permittivity*ElectricField")
                create_edge_model_derivatives(device, region,
                                              "contactcharge_edge",
                                              "Permittivity*ElectricField",
                                              "Potential")
                #  set_parameter(device=device, region=region, name=GetContactBiasName(contact), value=0.0)
            contact_bias_name = f"{contact_name}_bias"
            contact_model_name = f"{contact_name}nodemodel"
            contact_model = f"Potential -{contact_bias_name} + ifelse(NetDoping > 0, -V_t*log({CELEC_MODEL!s}/n_i), V_t*log({CHOLE_MODEL!s}/n_i))"\

            CreateContactNodeModel(device, contact_name, contact_model_name,
                                   contact_model)
            # Simplify it too complicated
            CreateContactNodeModel(
                device, contact_name, "{0}:{1}".format(contact_model_name,
                                                       "Potential"), "1")
            if is_circuit:
                CreateContactNodeModel(
                    device, contact_name,
                    "{0}:{1}".format(contact_model_name,
                                     contact_bias_name), "-1")

            if is_circuit:
                contact_equation(device=device,
                                 contact=contact_name,
                                 name="PotentialEquation",
                                 variable_name="Potential",
                                 node_model=contact_model_name,
                                 edge_model="",
                                 node_charge_model="contactcharge_node",
                                 edge_charge_model="contactcharge_edge",
                                 node_current_model="",
                                 edge_current_model="",
                                 circuit_node=contact_bias_name)
            else:
                contact_equation(device=device,
                                 contact=contact_name,
                                 name="PotentialEquation",
                                 variable_name="Potential",
                                 node_model=contact_model_name,
                                 edge_model="",
                                 node_charge_model="contactcharge_node",
                                 edge_charge_model="contactcharge_edge",
                                 node_current_model="",
                                 edge_current_model="")
            # Biggie

        # Initial DC solution
        solve(type="dc",
              absolute_error=1.0,
              relative_error=1e-10,
              maximum_iterations=30)

        drift_diffusion_initial_solution(device, region)

        solve(type="dc",
              absolute_error=1e10,
              relative_error=1e-10,
              maximum_iterations=30)
Esempio n. 8
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def create_solution(device, region, name):
    """
        Creates both node and edge solutions.
    """
    ds.node_solution(name=name, device=device, region=region)
    ds.edge_from_node_model(node_model=name, device=device, region=region)