The Transition Boundary Condition is used on interior boundaries to model a sheet of a highly conducting medium with a thickness relatively smaller than the characteristic size and curvature of the objects being modeled.

where the surface and transfer impedances are found as (Ref. 7):

where ω = 2πf, and

The above relations can be simplified depending of the ratio of the layer thickness ds and the skin depth δ(ω) that can be calculated as

In the Transition Boundary Condition section, you can select the boundary Type

The Electrically thick layer option decouples the two domains adjacent to the boundary. This setting is suitable, for example, when the thickness exceeds several times the skin depth. The condition becomes effectively equivalent to two Impedance Boundary Condition which are applied independently on two sides of the layer. This option can be also considered as a high-frequency case, since the skin depth becomes smaller as the frequency increases.

If the thickness is significantly smaller than the skin depth, select Electrically very thin layer. The tangential electric field is assumed to be continuous over the boundary in this case. This option can be also considered as a low-frequency case, as the skin depth becomes larger as the frequency decreases.

The defaults use the values From material, taking the properties from the material specified for the boundary. For User defined, enter different values or expressions.

For time dependent and eigenfrequency study, the approximation for the layer admittance is precomputed for Electrically very thin layer case to be valid when

where δ is the skin depth.

For Electrically thin layer, it is precomputed to cover the range:

For Electrically thick layer the approximation needs to be computed using the Time Domain and Eigenfrequency section.

This section becomes available only in case of Electrically thick layer. Use this section to configure and compute approximation of the surface admittance, which is needed for time domain and eigenfrequency computations. For other layer types, computations using time dependent or eigenfrequency study will work automatically, and they do not require any further inputs.

For Electrically thick layer, you need to specify the range of validity of the approximation because this layer type can represent a high-frequency case. For Frequency range, you can specify either Bandwidth and center (default) or Minimum and maximum.

In both cases, you can specify the approximation Accuracy. Note that both higher accuracy and wider frequency range can require using more auxiliary variables together with the corresponding ODEs to be solved during time domain and frequency computations.

The approximation computation needs to be done as a preprocessing step. Use the Compute approximation () action button available in the upper-right corner of Time Domain and Eigenfrequency section. The approximation computation is quick, and it will also compute and show the skin depth value at the center frequency. Once the computation has been performed, you can preview it using the Preview plot () action button that will become active at this section. You can also check the Show approximation data checkbox to inspect the actual computed values.