Lecture 5

Lecture 5 • Microwave Resonators • Series and Parallel Resonant Circuits • Transmission Line Resonators • A Gap-Coupled Microstrip Resonator EE 41139

Microwave Resonators • microwave resonators are used in many applications • filters, oscillators, frequency meters, tuned amplifiers • its operations are very similar to the series and parallel RLC resonant circuits EE 41139

Microwave Resonators • we will review the series and parallel RLC ciruits and discuss the implementation of the microwave resonators using distributive elements such as the microstrip line, rectangular and circular cavities, etc. EE 41139

Series and Parallel RLC Circuits • consider the series RLC resonator shown below: EE 41139

Series and Parallel RLC Circuits • the input impedance Zin is given by • -------(1) • the average complex power delivered to the resonator is EE 41139

Series and Parallel RLC Circuits • the average power dissipated by the resistor is • recall that the energy stored in the inductor is • the time-averaged energy stored in the inductor is EE 41139

Series and Parallel RLC Circuits • similarly, the time-averaged energy stored in the capacitor is • the input impedance can then be expressed as follows: • -----(2) EE 41139

Series and Parallel RLC Circuits • at resonance, the average stored magnetic and electric energies are equal, therefore, we have • and the resonance frequency is defined as EE 41139

Series and Parallel RLC Circuits • the quality factor is defined as the product of the angular frequency and the ratio of the average energy stored to energy loss per second • Q is a measure of loss of a resonant circuit, lower loss implies higher Q and high Q implies narrower bandwidth EE 41139

Series and Parallel RLC Circuits • at resonance We = Wm and we have • ----(3) • when R decreases Q increases as R dictates the power loss EE 41139

Series and Parallel RLC Circuits • the input impedance can be rewritten in the following form: EE 41139

Series and Parallel RLC Circuits • near by the resonance, i.e., , we can define and • ----(4) EE 41139

Series and Parallel RLC Circuits • the above form is useful for finding equivalent circuit near the resonance, for example, we can find out the resistance at resonance and so as L • for practical resonators, the loss is small; therefore, we can start with the lossless case and include the effect of the loss afterward EE 41139

Series and Parallel RLC Circuits • Consider the equation • As • ------(5) EE 41139

Series and Parallel RLC Circuits • From the EQ.4, when R = 0 for the lossless case, therefore, we can define a complex effective frequency • ----(6) so that, • --- (7) to incorporate the loss EE 41139

Series and Parallel RLC Circuits • From EQ.4 we have • the half-power fractional bandwidth (Zin=R/ ) is • And therefore Q = 1/BW ---(8) EE 41139

Series and Parallel RLC Circuits • now let us turn our attention to the parallel RLC resonator: EE 41139

Series and Parallel RLC Circuits • The input impedance is equal to • -----(9) • At resonance, and • , same results as in series RLC EE 41139

Series and Parallel RLC Circuits • the quality factor, however, is different EE 41139

Series and Parallel RLC Circuits • contrary to series RLC, the Q of the parallel RLC increases as R increases • similar to series RLC, we can derive an approximate expression for parallel RLC near resonance EE 41139

Series and Parallel RLC Circuits • Given EE 41139

Series and Parallel RLC Circuits • ----(11) EE 41139

Series and Parallel RLC Circuits • similar to the series RLC case, the effect of the loss can be incorporated into the lossless result by defining a complex frequency equal to • -----(12) • as in the series case, the half-power bandwidth is given by BW=1/Q --- (13) EE 41139

Loaded and Unloaded Q • Q defined above is a characteristic of the resonant circuit, this will change when the circuit is connected to a load EE 41139

Loaded and Unloaded Q • if the load is connected with the series RLC, the resistance in the series RLC is given by R’=R+RL, the corresponding quality factor QL becomes EE 41139

Loaded and Unloaded Q --- (13) • on the other hand, if the load is connected with the parallel RLC, we have 1/R’=1/R+1/RL EE 41139

Loaded and Unloaded Q -----------(14) EE 41139

Transmission Line Resonators • we discuss the use of transmission lines to realize the RLC resonator • for a resonator, we are interested in Q and therefore, we need to consider lossy transmission lines EE 41139

Short-Circuited l/2 Line • Consider the transmission line equation • for the transmission line shown below: • for a short-circuited line EE 41139

Short-Circuited l/2 Line • Given , • , • And tanh(jx)=jtan(x) • -------(15) EE 41139

Short-Circuited l/2 Line • note that • tanh(A+B)=(tanh A + tanh B)/(1+ tanh A tanh B), EQ. (15) becomes • our goal here is to compare the above equation with either EQ. (4) or EQ. (11) so that we can find out the corresponding R, L and C EE 41139

Short-Circuited l/2 Line • Assuming a TEM line so that • , for • We have • knowing that tan d = d when d is small EE 41139

Short-Circuited l/2 Line • note that the loss is usually very small and therefore, the input impedance can be rewritten as: • --------(16) EE 41139

Short-Circuited l/2 Line • comparing EQ. (16) and EQ. (4) where • ,we have • ----------(17) • at resonance, Zin = R and this will occur for l = nl/2---(18) EE 41139

Short-Circuited l/2 Line • The quality factor is given by • ----(19) • Q increases as the attenuation decreases EE 41139

Short-Circuited l/4 Line • recall that the input impedance of a short-circuited line is given by EE 41139

Short-Circuited l/4 Line • For , we have EE 41139

Short-Circuited l/4 Line • The input impedance can be written as, • --------(20) EE 41139

Short-Circuited l/4 Line • comparing EQ. (16) and EQ. (11) where • ,we have • ---(21) EE 41139

Short-Circuited l/4 Line • The quality is given by, • ---(22) • same as short-circuited l/2 line, Q increases as the attenuation decreases EE 41139

Open-Circuited l/2 Line • Consider the transmission line equation, • for the transmission line shown below: EE 41139

Open-Circuited l/2 Line • for an open-circuited line EE 41139

Open-Circuited l/2 Line • the input impedance for the open-circuited l/2 line can be rewritten as: • ------(23) EE 41139

Open-Circuited l/2 Line • comparing EQ. (23) and EQ. (11) where • , we have • -----(24) EE 41139

Open-Circuited l/2 Line • at resonance, Zin = R and this will occur for l = nl/2---(25) • the quality factor is given by • ----(26) • Q increases as the attenuation decreases, same as the short-circuited l/2 line EE 41139

Coupling to Resonators • to obtain maximum power transfer between a resonator and a feed line, the resonator must be matched to the feed at the resonant frequency • let us consider a series resonant circuit with the input impedance given by • EQ. (4), EE 41139

Coupling to Resonators • The unload Q is given by and for a matched load, R = Zo • the external Qe is given by where RL = Zo • for the resonator is matched to the feed at the resonant frequency, the external Qe is equal to Q, this is what we refer as critical coupling EE 41139

Coupling to Resonators • a coupling coefficient g is defined as • ----(27) • g < 1, undercoupled • g = 1, critically coupled • g > 1, overcoupled EE 41139

Design of a Gap-Coupled Microstrip Resonator • Objectives: • to design and fabricate a l/2 open-circuited microstrip resonator with a gap coupled microstrip feed line, the resonance frequency should be close to 5 GHz. EE 41139

Design of a Gap-Coupled Microstrip Resonator • to investigate overcoupled, critically coupled and undercoupled resonators • to use closed-form formulas for circuit design and simulations EE 41139

Lecture 5

Lecture 5

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Lecture 5

Lecture 5

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