Driven Solutions

Modal

For calculating the mode-based S-parameters of passive, high-frequency structures such as microstrips, waveguides, and transmission lines which are "driven" by a source, and for computing incident plane wave scattering. Network Analysis is the default and functions as before.

Composite Excitation provides a method for solving fields in a large frequency domain problem.

Terminal

For calculating the terminal-based S-parameters of passive, high-frequency structures with multi-conductor transmission line ports which are "driven" by a source.

This solution type results in a terminal-based description in terms of voltages and currents. Some modal data is also available.

Network Analysis is the default and functions as before.

Composite Excitation provides a method for solving fields in a large frequency domain problem.

Transient

For calculating problems in the time domain. It employs a time-domain (“transient”) solver. For Transient your choice of Composite Excitation or Network Analysis affects the options for the setup. If you select Network Analysis the setup includes an Input Signal tab for the simulation.

Typical transient applications include, but are not limited to:

• Simulations with pulsed excitations, such as ultra-wideband antennas, lightning strikes, electro-static discharge;

• field visualization employing short-duration excitations;

• time-domain reflectometry.

Not Driven

Eigenmode

For calculating the eigenmodes, or resonances, of a structure. The Eigenmode solver finds the resonant frequencies of the structure and the fields at those resonant frequencies. Eigenmode designs cannot contain design parameters that depend on frequency, for example a frequency-dependent impedance boundary condition.