Simulation Models
Supported mesh formats
The config["Model"]
object is used to specify the mesh for the discretized computational domain. In general, inputs are expected to be dimensional nondimensionalized internally. A length scale, specified under config["Model"]["L0"]
, describes the length units of the mesh relative to 1 meter (i.e. config["Model"]["L0"]: 1.0e-6
if the mesh coordinates are in $\mu$m, this is the default value). All other entries in the configuration file which have units of length should be specified in units of config["Model"]["L0"]
m.
MFEM supports a wide variety of mesh formats. In addition, Palace has built-in support for Nastran (.nas
, .bdf
) and COMSOL (.mphtxt
, .mphbin
) format mesh files, for both linear and high-order curved elements.
Geometric attributes for domains and boundaries in the mesh are used to define material properties and boundary conditions on the desired model regions and surfaces (see config["Domains"]
and config["Boundaries"]
). These attribute integers correspond to tags for the domain and boundary elements in the mesh, and should be non-negative and start at 1. They do not need to be contiguous in the mesh file. Throughout the configuration file, the "Attributes"
keyword is used to indicate which domain or boundary attributes are relevant to the material properties or boundary conditions being specified.
Mesh refinement
Refinement of the input mesh file can be performed using levels of global uniform refinement or region-based refinement, specified using the config["Model"]["Refinement"]
object. The user can specify any combination of uniform refinement levels as well as local refinement regions which refines the elements inside of a certain box or sphere-shaped region. For simplex meshes, the refinement maintains a conforming mesh but meshes containing hexahedra, prism, or pyramid elements will be nonconforming after local refinement (this is not supported at this time).
Adaptive mesh refinement (AMR) according to error estimates calculated from the computed solution can also be specified using the config["Model"]["Refinement"]
object. Nonconformal refinement is supported for all mesh types, and additionally conformal refinement is supported for simplex meshes. AMR is available for all problem types apart from driven problems in the time domain.
Material models
Material properties are handled by the config["Domains"]["Materials"]
object. Palace supports linear, frequency independent constitutive laws for material modeling.
Materials with scalar or symmetric matrix-valued material properties are supported. For most simulation types, each material in the model requires a specified relative permittivity and relative permeability (for electrostatic simulations, only the permittivity is required, while for magnetostatics, only the permeability is required). For dielectric domains, a loss tangent may be specified. Alternatively, for normal conducting domains, an electrical conductivity may be specified which is used to relate the current density and electric field via Ohm's law.
Modeling of superconducting domains is performed using the current-field constitutive relations given by the London equations. The user can specify a London penetration depth to activate this model. It can also be used in conjunction with a materal conductivity when wishing to model both superconducting and normal currents.