7.8: Summary

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This chapter presented design concepts for realizing matching networks with broad bandwidths. Matching a load and/or a source with a reactance presents a particular problem because reactive loads include energy storage elements and energy storage elements limit bandwidth. Theoretically, if negative capacitances and inductors could be realized then it would be possible to have infinite bandwidth matching of complex loads and/or sources provided that the elements of the matching network are lossless. Since negative capacitors and inductors cannot be realized, there will be a limit on matching bandwidth. The Fano-Body limits indicate the tradeoff between the quality of the match in terms of the minimum reflection coefficient that can be achieved and the bandwidth of the match. While ideal magnetic transformers can achieve infinite matching of source and load resistors, actual magnetic transformers have self inductances and thus energy storage and so matching bandwidth is limited even with magnetic transformers.

All matching networks introduce energy storage elements. This includes capacitor, inductor, and transmission line elements, as well as magnetic transformers. Thus design techniques are required that enable design tradeoffs of the quality of a match and bandwidth. The constant \(Q\) circles on a Smith chart enable the maximum \(Q\) and hence fractional bandwidth, which is very approximately \(1/Q\), of a matched to be controlled. As long as the locus of the input reflection coefficient of an evolving terminated matching network does not go outside a specific pair of equal-valued constant \(Q\) circles the bandwidth is constrained. This concept applies to loads and sources that are resistive only or include reactances. The stepped-impedance and tapered transmission-line matching networks presented enable broadband matching of source and load resistances but the concepts of gradual matching in stages to interim resistances levels can be extrapolated to matching general sources and loads.

The final concept of this chapter describes a topology for matching a reactive load, in particular a load comprising a resistor and a capacitor. This is what the input and output of a transistor looks like. The matching network described in Section 7.7 approximates a negative capacitor over a limited bandwidth and is one of the best such networks known and this matching network topology is commonly used in matching the input and output of transistors. Other broadband network topologies have been invented and these developments are tracked by microwave engineers involved in matching network design.

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