Image impedance

Image impedance is a concept used in electronic network design and analysis and most especially in filter design. The term image impedance applies to the impedance seen looking into a port of a network. Usually a two-port network is implied but the concept can extended to networks with more than two ports. The definition of image impedance for a two-port network is the impedance, Z_i 1, seen looking into port 1 when port 2 is terminated with the image impedance, Z_i 2, for port 2. In general, the image impedances of ports 1 and 2 will not be equal unless the network is symmetrical (or anti-symmetrical) with respect to the ports.

As an example, the derivation of the image impedances of a simple 'L' network is given below. The L network consists of a series impedance, Z, and a shunt admittance, Y.

The difficulty here is that in order to find Z_i 1 it is first necessary to terminate port 2 with Z_i 2. However, Z_i 2 is also an unknown at this stage. The problem is solved by terminating port 2 with an identical network: port 2 of the second network is connected to port 2 of the first network and port 1 of the second network is terminated with Z_i 1. The second network is terminating the first network in Z_i 2 as required. Mathematically, this is equivalent to eliminating one variable from a set of simultaneous equations. The network can now be solved for Z_i 1. Writing out the expression for input impedance gives;

and solving for Z_{i 1},

Z_i 2 is found by a similar process, but it is simpler to work in terms of the reciprocal, that is image admittance Y_i 2,

Also, it can be seen from these expressions that the two image impedances are related to each other by;

Directly measuring image impedance by adjusting terminations is inconveniently iterative and requires precision adjustable components to effect the termination. An alternative technique to determine the image impedance of port 1 is to measure the short-circuit impedance Z_SC (that is, the input impedance of port 1 when port 2 is short-circuited) and the open-circuit impedance Z_OC (the input impedance of port 1 when port 2 is open-circuit). The image impedance is then given by,

This method requires no prior knowledge of the topology of the network being measured.

When used in filter design, the 'L' network analysed above is usually referred to as a half section. Two half sections in cascade will make either a T section or a Π section depending on which port of the L section comes first. This leads to the terminology of Z_i T to mean the Z_i 1 in the above analysis and Z_i Π to mean Z_i 2.

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