A Y-parameter matrix describes the behaviour of any linear electrical network that can be regarded as a black box with a number of ports. A port in this context is a pair of electrical terminalscarrying equal and opposite currents into and out of the network, and having a particular voltage between them. The Y-matrix gives no information about the behaviour of the network when the currents at any port are not balanced in this way, nor does it give any information about the voltage between terminals not belonging to the same port. Typically, it is intended that each external connection to the network is between the terminals of just one port, so that these limitations are appropriate. For a generic multi-port network definition, it is assumed that each of the ports is allocated an integer n ranging from 1 to N, where N is the total number of ports. For port n, the associated Y-parameter definition is in terms of the port voltage and port current, and respectively. For all ports the currents may be defined in terms of the Y-parameter matrix and the voltages by the following matrix equation: where Y is an N × N matrix the elements of which can be indexed using conventional matrix notation. In general the elements of the Y-parameter matrix are complex numbers and functions of frequency. For a one-port network, the Y-matrix reduces to a single element, being the ordinary admittance measured between the two terminals.
The Y-parameter matrix for the two-port network is probably the most common. In this case the relationship between the port voltages, port currents and the Y-parameter matrix is given by: where For the general case of an N-port network,
Admittance relations
The input admittance of a two-port network is given by: where YL is the admittance of the load connected to port two. Similarly, the output admittance is given by: where YS is the admittance of the source connected to port one.
In the special case of a two-port network, with the same and real characteristic admittance at each port, the above expressions reduce to Where The above expressions will generally use complex numbers for and. Note that the value of can become 0 for specific values of so the division by in the calculations of may lead to a division by 0. The two-port S-parameters may also be obtained from the equivalent two-port Y-parameters by means of the following expressions. where and is the characteristic impedance at each port.
Relation to Z-parameters
Conversion from Z-parameters to Y-parameters is much simpler, as the Y-parameter matrix is just the inverse of the Z-parameter matrix. The following expressions show the applicable relations: Where In this case is the determinant of the Z-parameter matrix. Vice versa the Y-parameters can be used to determine the Z-parameters, essentially using the same expressions since And