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Lesson 23: AC Resonance

Lesson 23: AC Resonance. Learning Objectives. Become familiar with the frequency response of a series resonant circuit and how to calculate the resonant and cutoff frequencies. Be able to calculate a tuned network’s quality factor, bandwidth, and power levels at important frequency levels.

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Lesson 23: AC Resonance

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  1. Lesson 23: AC Resonance

  2. Learning Objectives • Become familiar with the frequency response of a series resonant circuit and how to calculate the resonant and cutoff frequencies. • Be able to calculate a tuned network’s quality factor, bandwidth, and power levels at important frequency levels. • Become familiar with the frequency response of a parallel resonant circuit and how to calculate the resonant and cutoff frequencies. • Understand the impact of the quality factor on the frequency response of a series or parallel resonant network. • Begin to appreciate the difference between defining parallel resonance at the frequency either where the input impedance is a maximum or where the network has a unity power factor.

  3. Resonance Introduction • Resonant (or tuned)circuits, are fundamental to the operation of a wide variety of electrical and electronic systems in use today. • The resonant circuit is a combination of R, L, and Celements having a frequency response characteristic similar to the one below:

  4. Resonance Introduction • The resonant electrical circuit must have both inductance and capacitance. • In addition, resistance will always be present due either to the lack of ideal elements or to the control offered on the shape of the resonance curve. • When resonance occurs due to the application of the proper frequency ( fr), the energy absorbed by one reactive element is the same as that released by another reactive element within the system. • Remember:

  5. Series resonant circuit. Phasordiagram for the series resonant circuit at resonance. Power triangle for the series resonant circuit at resonance. Series Resonant Circuit The basic format of the series resonant circuit is a series R-L-C combination in series with an applied voltage source.

  6. XL versus f XC versus f ZT Versus Frequency • Knowing that XC and XL are dependent upon frequency it can be stated: • Capacitor Impedance decreases as frequency increases. • Inductor Impedance increases as frequency increases. • This implies that the total impedance of the series R-L-C circuit below, at any frequency, is determined by:

  7. ZT Versus Frequency • The total-impedance-versus-frequency curve for the series resonant circuit below can be found by applying the impedance-versus-frequency curve for each element of the equation previously shown, written in the following form: • When XL=XC the resonant frequency (fr) can be found. Frequency response of XLand XC of a series R-L-C circuit on the same set of axes

  8. The Resonant Frequency (fr) • To find fr, set the impedances equal and solve: • This is the key equation for resonance. Total impedance at this point is shown to the right: ZTversus f

  9. I versus f for the series resonant circuit Current Versus Frequency • If impedance is minimum at fr, current will be at a maximum: • If we now plot the magnitude of the current versus frequency for a fixed applied voltage E, we obtain the curve showing that current is maximum at fr:

  10. Bandwidth (BW) • Band frequencies are those that define the points on the resonance curve that are 0.707 ( ) of the peak current or voltage. • Bandwidth (BW) is the range of frequencies between the band, or ½ power frequencies. Defined by:

  11. The Quality Factor (Q) • The quality factor (Q) of a series resonant circuit is defined as the ratio of the reactive power of either the inductor or the capacitor to the average power of the resistor at resonance. • Q can be found several ways: • This also gives an alternate way to find BW:

  12. Example Problem 1 Determine fr, Q, BW and the current (I) at resonance. Plot the current vs. frequency and label fr, f1, f2and BW. R=1Ω Because we are at fr we know that XL = XC, but just to show it: We know XL so we can find Q: Now let’s find f1 and f2 and then plot: We know Q so we can find BW: Now find Imax: Remember, since XL=XC at resonance, they cancel out for ZTand only R is left.

  13. Example Problem 2 • Find I, VR, VC, VLat resonance. • Determine Q for the circuit. • If the fr is 5 kHz, what is the BW? • With fr= 5kHz what are the values of L and C? • What is the power dissipated in the circuit at the half-power frequency? XL=30Ω XC=30Ω E=50mV

  14. In case you were wondering about KVL from the last problem, the below plot is what is happening with VL and VC at resonance. VR follows the I curve. Until fr is reached, VC builds up from a value equal to the input voltage (E) because the reactance of the capacitor is infinite (open circuit) at zero frequency, but then decreases toward zero. VL increases from zero until fris reached, but then decreases to E. Notice, again, that VL = VCat the resonant frequency. VR, VL, VC, and I for a series resonant circuit where Qs ≥10 VR, VL, AND VC

  15. Ideal parallel resonant network Parallel Resonant Circuit • The basic format of the parallel resonant circuit is a parallel R-L-C combination with an applied current source. • The parallel resonant circuit has the basic configuration shown below:

  16. Parallel Resonant Circuit Equivalent parallel network for a series R-L combination Substituting the equivalent parallel network for the series R-L combination Substituting R =Rs║Rp for the network Practical parallel L-C network

  17. Parallel Resonant Circuit • Unity Power Factor,fp: • Maximum Impedance, fm:

  18. Parallel Resonant Circuit ZTversus frequency for the parallel resonant circuit

  19. Parallel Resonant Circuit Phase plot for the parallel resonant circuit

  20. Effect Of Ql≥ 10 • The content of the previous section may suggest that the analysis of parallel resonant circuits is significantly more complex than that encountered for series resonant circuits. • Fortunately, however, this is not the case since, for the majority of parallel resonant circuits, the quality factor of the coil Qlis sufficiently large (Ql≥10) to permit a number of approximations that simplify the required analysis.

  21. Approximate equivalent circuit for Ql≥ 10 Effect Of Ql≥ 10 • Inductive Reactance: • Resonant Frequency, fp (Unity Power Factor) and Resonant Frequency, fm (Max VC): • Rp • ZTp • Qp

  22. Establishing the relationship between IC and IL and the current IT Effect Of Ql≥ 10 • BW • IL and IC

  23. Summary Table

  24. Example Problem 3 Find the resonant frequency (fr), Q, BW, f1, f2and draw the frequency response for the circuit below: Imax = 20mA f1 48.75kHz fr 50kHz f2 51.25kHz

  25. QUESTIONS?

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