Use the Port node where electromagnetic energy enters or exits the model. A port can launch and absorb specific modes. Use the boundary condition to specify wave type ports. Ports support S-parameter calculations but can be used just for exciting the model. This node is not available with the Electromagnetic Waves, Transient interface.

In 3D, the following subnodes are available from the context menu, by right-clicking the Port node, or from the Physics toolbar, Attributes menu:

Enter a unique Port name. Only nonnegative integer numbers can be used as Port name as it is used to define the elements of the S-parameter matrix and numeric port names are also required for port sweeps and Touchstone file export.

Select the Type of Port — User defined, Numeric, Transverse electromagnetic (TEM), Rectangular, Coaxial, Circular, or Periodic.

Periodic ports are available in 3D and 2D. Circular and Coaxial ports are available in 3D and 2D axisymmetry.

Numeric ports require a Boundary Mode Analysis study type. It should appear before the frequency domain study node in the study branch of the model tree. If more than one numeric port is needed, use one Boundary Mode Analysis node per port and assign each to the appropriate port. Then, it is best to add all the studies; Boundary Mode Analysis 1, Boundary Mode Analysis 2, …, Frequency Domain 1, manually. Numeric ports are by default computed for the deformed mesh whereas other types of ports compute the mode shape using geometry information.

Transverse electromagnetic (TEM) ports are only available in 3D models. It requires a TEM Boundary Mode Analysis study type. It should appear before the frequency domain study node in the study branch of the model tree. Add Ground and Electric Potential subnodes to compute the port mode field and impedance. These subnodes are available from the context menu (right-click the Port parent node) or from the Physics toolbar, Attributes menu. Enter a Characteristic impedance Zref (SI unit: Ω). The default is 50 Ω. The characteristic impedance of a port is calculated using the square root of the ratio of the inductance and capacitance. The electric mode field on a port boundary is scaled by the ratio between the computed mode characteristic impedance and Zref.

To set whether it is an inport or a listener port, select On or Off from the Wave excitation at this port list. If On is selected, enter a Port input power Pin (SI unit: W) or a Deposited power Pdep (SI unit: W) if the Enable active port feedback check box is marked. When a Deposited power is specified, the input power is adjusted so that the power that is not reflected equals the specified Deposited power. If Enable active port feedback is marked this must be the only inport.

Select the Activate slit condition on interior port check box to use the Port boundary condition on interior boundaries.

Then select a Slit type — PEC-backed (the default) or Domain-backed. The PEC-backed type makes the port on interior boundaries perform as it does on exterior boundaries. The Domain-backed type can be combined with perfectly matched layers to absorb the excited mode from a source port and other higher order modes.

Click Toggle Power Flow Direction button to define the power flow for the port. For an excited port, the power flow should point in to the excited domain and for a listener port the power flow should point out from the excited domain. The power flow direction is visualized with a red arrow on the port boundary in the Graphics window.

This check box is available for 3D components and when the Type of port is Numeric.

Select the Analyze as a TEM field check box to add Integration Line for Current and Integration Line for Voltage subnodes. These subnodes are available from the context menu (right-click the Port parent node) or from the Physics toolbar, Attributes menu.

Enter a reference Characteristic impedance Zref (SI unit: Ω). The default is 50 Ω. The characteristic impedance of a port is calculated using the ratio of the voltage and current using Boundary Mode Analysis. The mode field on a port boundary is scaled by the ratio between the computed characteristic impedance and user-specified Zref.

The input is based on the Type of Port selected above — User Defined, Rectangular, Circular, or Periodic. No entry is required if Numeric or Coaxial are selected.

Set the Mode phase θin (SI unit: rad) for the port mode field. The default is 0 radians. For instance, if the inspected port mode field is polarized in the opposite direction compared to the expected direction, a Mode phase of π (enter pi in the field) can be used for polarizing the mode field in the expected direction. Notice that a change of the Mode phase, either on the exciting or the listener port, changes also the S-parameter coupling the exciting and the listener port. However, a change of the Mode phase on the exciting port does not modify the reflection coefficient (normally denoted S11) associated with the exciting port.

For User defined specify the eigenmode of the incoming wave at the port. Even if Wave excitation at this port is set to Off, the mode field should represent the incoming wave that corresponds to the actual outgoing wave. The mode field can be entered with an arbitrary amplitude and is normalized internally.

For Rectangular specify a unique rectangular mode.

For 3D components, select a Mode type — Transverse electric (TE) or Transverse magnetic (TM). Enter the Mode number, for example, 10 for a TE10 mode, or 11 for a TM11 mode.

For 2D components, to excite the fundamental mode, select the mode type Transverse electromagnetic (TEM), since the rectangular port represents a parallel-plate waveguide port that can support a TEM mode. Only TE modes are possible when solving for the out-of-plane vector component, and only TM and TEM modes are possible when solving for the in-plane vector components. There is only a single mode number, which is selected from a list.

In 2D axisymmetry, Coaxial does not support nonzero azimuthal mode number. The Azimuthal mode number in the Physics interface should be defined as zero.

For Circular specify a unique circular mode.

For 3D components, enter the Mode number, for example, 11 for a TE11 mode, or 01 for a TM01 mode. When Circular is selected as the type of port in 3D, the Circular Port Reference Axis subnode is available from the context menu (right-click the parent node) or from the Physics toolbar, Attributes menu. It defines the orientation of fields on a port boundary.

For 2D axisymmetry components, select whether the Azimuthal mode number is defined in the Physics interface or if it is User defined. For User defined define an integer constant or an integer parameter expression for the Azimuthal mode number. Note that the absolute value of the Azimuthal mode number must be less than 11.

For Periodic specify parameters for the mode field. When Periodic is selected, the Diffraction Order port subnode is available from the context menu (right-click the parent node) or from the Physics toolbar, Attributes menu.

Select a Input quantity — Electric field or Magnetic field and define the mode field amplitude for the incoming wave at the port. Even if Wave excitation at this port is set to Off, the mode field amplitude should represent the incoming wave that corresponds to the actual outgoing wave.

For 3D components, if Wave excitation at this port is On, define the Elevation angle of incidence and Azimuth angle of incidence. The Elevation angle of incidence α1 and Azimuth angle of incidence α2 are used in the relations

where k is the wave vector, kparallel is the projection of k onto the port, kF is the k-vector for Floquet periodicity, n is the outward unit normal vector to the boundary, and is one of the normalized primitive unit cell vectors from the periodic structure defined from Periodic Port Reference Point.

The Elevation angle of incidence α1 is the angle between n and k.

The Azimuth angle of incidence is the counterclockwise rotating angle from the primitive vector a1 around the axis built with Periodic Port Reference Point and n.

For periodic ports with hexagonal port boundaries, the definition of the vector a1 is slightly different from the default definition. In this case, the unit cell is actually a rhomboid, with primitive vectors pointing in other directions than the side vectors of the hexagon. Thus, for a hexagonal periodic port, the vector a1 is defined along one of the sides of the hexagon, and it is not one of the primitive vectors of the hexagonal point lattice. The Azimuth angle of incidence α2 is still measured from the vector a1, even though this vector now refers to a side vector of the hexagonal port boundary and not a primitive vector.

For 2D components define the Angle of incidence. The Angle of incidence α is defined by the relation

where k is the projection of the wave vector in the xy-plane, n is the normalized normal vector to the boundary, k is the magnitude of the projected wave vector in the xy-plane, and z is the unit vector in the z direction.

Default Polarization plots are automatically generated for Periodic ports in 3D and in 2D, if the Electric field components solved for setting in the Components section for the physics interface is set to Three-component vector. The Polarization plot includes polarization ellipses for each diffraction order. The polarization ellipse line graphs are generated by plotting the in-plane Jones vector element versus the out-of-plane Jones vector element.

This section is only available for Periodic ports to provide parameter settings that are used when automatically adding Diffraction Order subnodes to Periodic ports.

When all parameters are defined, click the Add Diffraction Orders button from the exciting Periodic port to automatically create Diffraction Order ports as subnodes to all Periodic ports having the Include in automatic diffraction order calculation check box selected.

This utility is available for Rectangular and Circular port types. Enter a Relative permittivity (default is 1) of the material fully filled in a waveguide and then click the Compute Waveguide Cutoff Frequency button to compute the cutoff frequency for the particular waveguide geometry and the selected Mode type. The result is displayed in the Messages window.

Set the Port Offset doffset (SI unit: m) for the de-embedded S-parameter calculation. The default is 0 m. The phase of the de-embedded S-parameters is adjusted from the calculated S-parameters with the propagation constant and the value of doffset.

where m is the source port name, n is the listener port name, β is propagation constant, and d is offset distance from the port boundary.

The de-embedding functionality is triggered when doffset is set to a nonzero value. It is assumed that the domain between the port boundary and the boundary projected by the doffset is straight, while maintaining a constant cross-sectional shape.

To display this section, click the Show More Options button () and select Advanced Physics Options in the Show More Options dialog box. For information about the Constraint Settings section, see Constraint Settings in the COMSOL Multiphysics Reference Manual.