Abstract: A method and system of calibrating first and second adapters comprises the steps of calibrating coaxial ports of a vector network analyzer to traceable standards and connecting a symmetrical through circuit path between the coaxial ports. The through circuit path comprises a cascaded combination of the first and second adapters. The first adapter is passive and substantially identical to the second adapter and uncascaded first and second adapters comprise a measurement device path. The through circuit path and the measurement device path have substantially equivalent S-parameters. S-parameters of the through circuit path are measured and then the first and second adapters are characterized based upon the measured S-parameters. The method and system may be applied to two port adapters and devices under test and may also be scaled for multi-port adapters and devices under test.

Abstract: A method of predicting electrical behavior of a device comprises the steps of representing at least one balanced matching network having a balanced input port and a balanced output port and further representing a connection between the matching network an a balanced output port and a balanced input port of a device. A matching network S-parameter matrix is calculated and a device S-parameter matrix is obtained either through a measurement or from a model. A cascaded S-parameter matrix for the matching network in combination with the device is calculated, and from the resulting cascaded S-parameter matrix, a mixed-mode cascaded S-parameters may be extracted. The mixed-mode cascaded S-parameters assist a designer in predicting and analyzing the electrical behavior of the differential and single-ended ports as well as the electrical Interaction therebetween.

Abstract: A method, apparatus and article of manufacture to aid in the characterization of a device establishes a device S-parameter matrix (SD) to represent electrical behavior of the device, an adapter T-parameter matrix (Ta) to represent all possible electrical paths through circuits to all device ports of the device, and a cascaded S-parameter matrix (Sc) to represent the circuits cascaded with the device. Values for the adapter T-parameter matrix are obtained either through measurement or modeling. The device cascaded with the circuits is measured to obtain values for the cascaded S-parameter matrix, permitting use of a general solution for the device S-parameter matrix as a function of the adapter T-parameter matrix and the cascaded S-parameter matrix.

Abstract: According to one embodiment of the invention, there is provided a method of calibrating an N-port multiport test system for measurement of a DUT. The method consists of coupling each port of an N-port automatic calibration device to a respective port of the N-port multiport test system, and presenting three reflection standards with the automatic calibration device to each port of the N-port multiport test system. The method also consists of providing with the automatic calibration device, N−1 through conditions of a possible N(N−1)/2 possible through conditions, between corresponding ports of the N-port multiport test system, and making measurements with the N-port multiport test system of the three reflection standards at each port and the N−1 through conditions between the corresponding ports. The method further consists of determining all of systematic error coefficients for all of the ports of N-port multiport test system.