Chebyshev Multi-section Matching The Chebyshev transformer is optimum bandwidth to allow ripple within the passband response, and is known as equally ripple. Larger bandwidth than that of binomial matching. The Chebyshev characteristics
Chebyshev Transformer Design
Example5.10: Design a three-section Chebyshev transformer to match a 100 load to a 50 line, with m=0.05? Solution
Using table design for N=3 and ZL/Z0=2 can find coefficient as 1 Using table design for N=3 and ZL/Z0=2 can find coefficient as 1.1475, 1.4142, and 1.7429. So Z1=57.37, Z2=70.71, and Z3=87.15.
Tapered Lines Matching The line can be continuously tapered instead of discrete multiple sections to achieve broadband matching. Changing the type of line can obtain different passband characteristics. Relation between characteristic impedance and reflection coefficient Three type of tapered line will be considered here 1) Exponential 2)Triangular 3) Klopfenstein
Exponential Taper The length (L)of line should be greater than /2(l>) to minimize the mismatch at low frequency.
Triangular Taper The peaks of the triangular taper are lower than the corresponding peaks of the exponential case. First zero occurs at l=2
Klopfenstein Taper For a maximum reflection coefficient specification in the passband, the Klopfenstein taper yields the shortest matching section (optimum sense). The impedance taper has steps at z=0 and L, and so does not smoothly join the source and load impedances.
Example5.11: Design a triangular, exponential, and Klopfenstein tapers to match a 50 load to a 100 line? Solution Triangular taper Exponential taper
Klopfenstein taper
Bode-Fano Criterion The criterion gives a theoretical limit on the minimum reflection magnitude (or optimum result) for an arbitrary matching network The criterion provide the upper limit of performance to tradeoff among reflection coefficient, bandwidth, and network complexity. For example, if the response ( as the left hand side of next page) is needed to be synthesized, its function is given by applied the criterion of parallel RC For a given load, broader bandwidth , higher m. m 0 unless =o. Thus a perfect match can be achieved only at a finite number of frequencies. As R and/or C increases, the quality of the match ( and/or m) must decrease. Thus higher-Q circuits are intrinsically harder to match than are lower-Q circuits.
Chapter 6 Microwave Resonators
RLC Series Resonant Circuit Microwave resonators are used in a variety of applications, including filters, oscillators, frequency meters, and tuned amplifiers. The operation of microwave resonators is very similar to that of the lumped-element resonators (such as parallel and series RLC resonant circuits) of circuit theory. RLC Series Resonant Circuit Vout Vin