Equation System
To derive the equation system in this physics interface, start with Faraday’s law:
The electric field is computed from the current density, using an appropriate constitutive relation:
where Je is an externally generated current density, v is the relative velocity of the domain in the physics interface’s or node’s frame, and Em(J) is a (possibly nonlinear) relation sometimes called E-J characteristic, which describes the electric field in the local (material) frame as a function of the current density. The total current density J is finally obtained from Ampère’s Law:
Combining these equations give the first equation in the system applied by the Magnetic Field Formulation interface:
This equation must be modified in different studies and according to the chosen constitutive relation. In stationary studies, the equation becomes:
while in frequency domain is:
The second equation in the system is the magnetic Gauss’ law:
This equation is added with two purposes:
In magnetostatics, the magnetic flux density B does not appear in the first equation. To allow modeling of magnetic materials and permanent magnets, it is necessary to include B (with its constitutive relation) through the Magnetic Gauss’ Law node.
E-J Characteristic for the Electric Field Computation
The Em(J) characteristic introduced in the previous section can be specified in different ways in the Faraday’s Law node. The most common case is a linear relation between Em and J. In magnetostatics and in time-dependent studies (in the quasistatic approximation) this relation is specified by the resistivity or the electrical conductivity:
σ and ρ can be tensor quantities, in which case the inverse is intended as the inverse of a tensor. In frequency-domain, the displacement current is included, giving the following relations:
If the E-J characteristic is nonlinear, such in the case of a superconductor, the function can be expressed explicitly or as a material property.
Superconducting Wire: Application Library path ACDC_Module/Other_Industrial_Applications/superconducting_wire