1. Chapter 21 Resonance

2. 2 Series Resonance Simple series resonant circuit –Has an ac source, an inductor, a capacitor, and possibly a resistor Z T = R + jX L – jX C = R + j(X L – X C ) –Resonance occurs when X L = X C –At resonance, Z T = R

3. 3 Series Resonance Response curves for a series resonant circuit

4. 4 Series Resonance

5. 5 Since X L =  L = 2  fL and X C = 1/  C = 1/2  fC for resonance set X L = X C –Solve for the series resonant frequency f s

6. 6 Series Resonance At resonance –Impedance of a series resonant circuit is small and the current is large I = E/Z T = E/R

7. 7 Series Resonance At resonance V R = IR V L = IX L V C = IX C

8. 8 Series Resonance At resonance, average power is P = I 2 R Reactive powers dissipated by inductor and capacitor are I 2 X Reactive powers are equal and opposite at resonance

9. 9 The Quality Factor,Q Q = reactive power/average power –Q may be expressed in terms of inductor or capacitor For an inductor, Q coil = X L /R coil

10. 10 The Quality Factor,Q Q is often greater than 1 –Voltages across inductors and capacitors can be larger than source voltage

11. 11 The Quality Factor,Q This is true even though the sum of the two voltages algebraically is zero

12. 12 Impedance of a Series Resonant Circuit Impedance of a series resonant circuit varies with frequency

13. 13 Bandwidth Bandwidth of a circuit –Difference between frequencies at which circuit delivers half of the maximum power Frequencies, f 1 and f 2 –Half-power frequencies or the cutoff frequencies

14. 14 Bandwidth A circuit with a narrow bandwidth –High selectivity If the bandwidth is wide –Low selectivity

15. 15 Bandwidth Cutoff frequencies –Found by evaluating frequencies at which the power dissipated by the circuit is half of the maximum power

16. 16 Bandwidth

17. 17 Bandwidth From BW = f 2 - f 1 BW = R/L When expression is multiplied by  on top and bottom –BW =  s /Q (rad/sec) or BW = f s /Q (Hz)

18. 18 Series-to-Parallel Conversion For analysis of parallel resonant circuits –Necessary to convert a series inductor and its resistance to a parallel equivalent circuit

19. 19 Series-to-Parallel Conversion If Q of a circuit is greater than or equal to 10 –Approximations may be made Resistance of parallel network is approximately Q 2 larger than resistance of series network –R P  Q 2 R S –X LP  X LS

20. 20 Parallel Resonance Parallel resonant circuit –Has X C and equivalents of inductive reactance and its series resistor, X LP and R S At resonance –X C = X LP

21. 21 Parallel Resonance Two reactances cancel each other at resonance –Cause an open circuit for that portion Z T = R P at resonance

22. 22 Parallel Resonance Response curves for a parallel resonant circuit

23. 23 Parallel Resonance From X C = X LP –Resonant frequency is found to be

24. 24 Parallel Resonance If (L/C) >> R –Term under the radical is approximately equal to 1 If (L/C)  100R –Resonant frequency becomes

25. 25 Parallel Resonance Because reactances cancel –Voltage is V = IR Impedance is maximum at resonance –Q = R/X C If resistance of coil is the only resistance present –Circuit Q will be that of the inductor

26. 26 Parallel Resonance Circuit currents are

27. 27 Parallel Resonance Magnitudes of currents through the inductor and capacitor –May be much larger than the current source

28. 28 Bandwidth Cutoff frequencies are

29. 29 Bandwidth BW =  2 -  1 = 1/RC If Q  10 –Selectivity curve becomes symmetrical around  P

30. 30 Bandwidth Equation of bandwidth becomes Same for both series and parallel circuits