Topic 2a ac_circuits_analysis
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This document summarizes key concepts related to AC circuits analysis including capacitors, inductors, and AC power calculations. Some main points: - Capacitors store energy in electric fields and consist of conducting plates separated by an insulator. Capacitance depends on plate area, distance, and dielectric material. Inductors store energy in magnetic fields and consist of coils of wire. Inductance depends on number of turns, length, and core material. - The voltage-current relationships for capacitors and inductors involve derivatives with respect to time. Power delivered to capacitors and inductors involves integrating these relationships. - Equivalent capacitance and inductance can be calculated for combinations of components in series
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Topic 2a ac_circuits_analysis
- 1. 1 Topic 2a :AC Circuits Analysis • Capacitors network • Inductors network • AC analysis – average power, rms power • Frequency response of RC and RL circuits.
- 2. 2 Capacitors • A capacitor is a passive element designed to store energy in its electric field. • A capacitor consists of two conducting plates separated by an insulator (or dielectric). • When a voltage source v is connected to the capacitor, the source deposits a charge q on one plate and a negative charge –q on the other. • q = Cv, where C is the capacitance of the capacitor.
- 3. 3 Capacitance • Capacitance is the ratio of the charge on one plate of a capacitor to the voltage difference between the two plates, measured in Farad (F). • For a parallel-plate capacitor. The capacitance is given by where A is the surface area of each plate, d is the distance between the two plates, and is the permitivity of the dielectric material. d A C
- 4. 4 Symbols for capacitors Variable capacitor Fixed capacitor Fixed capacitor
- 5. 5 Current- voltage relationship of the capacitor • Since different q = Cv gives • Voltage current relationship where v(to) is the voltage across the capacitor at time to. , dt dq i . dt dv Ci )( 1 or 1 o t t t tvidt C vidt C v o
- 6. 6 Power delivered to capacitor • The instantaneous power delivered to a capacitor is • Energy stored in the capacitor is • v(-) = 0 then . dt dv Cvvip t t CvvdvCdt dt dv vCpdtw tt 2 2 1 . 2 or 2 1 2 2 C q wCvw
- 7. 7 Important properties of capacitor 1. When the voltage across the capacitor is not changing with time, the current through the capacitor is zero. A capacitor is an open circuit to dc. 2. The voltage on the capacitor must be continuous. The voltage on a capacitor cannot change abruptly (suddenly). 2. The ideal capacitor does not dissipate energy. 3. A real capacitor has a parallel leakage resistance. The leakage resistance may be as high as 100 M.
- 8. 8 Example (a) Calculate the charge stored on a 3-pF capacitor with 20V across it. (b) Find the energy stored in the capacitor. Solution (a) (b) Energy stored .6020103 12 pCCvq .60020103 2 1 2 1 2122 pJCvw
- 9. 9 Example The voltage across a 5-F capacitor is Calculate the current through it. Solution The current is V.6000cos10)( ttv A.6000sin3.0 6000sin106000105 6000cos10 105)( 6 6 t t dt t)d( dt dv Cti
- 10. 10 Example If a 10-F capacitor is connected to a voltage source with determine the current through the capacitor. Solution The current is V.2000sin50)( ttv A.2000cos 2000cos5020001010 2000sin50 1010)( 6 6 t t dt t)d( dt dv Cti
- 11. 11 Example Determine the voltage across a 2-F capacitor if the current through it is Assume that the initial capacitor voltage is zero. Solution mA.6)( 3000t eti V.)1( )1( 0)3000(102 106 106 102 11 3000 30003000 6 3 0 30003 6 0 t tt t t t e e t e dteidt C v
- 12. 12 Example Obtain the energy in each capacitor under dc conditions
- 13. 13 Solution • Under dc conditions, replaced each capacitor with an open circuit. • Current through 2-k and 4k resistor is mA mAi 2 )6( 423 3
- 14. 14 Solution • Voltage v1 across capacitor 2 mF is • Voltage v2 across capacitor 4 mF is • Energy stored in capacitor 2 mF is • Energy stored in capacitor 4 mF is mJvCw 104102 2 1 2 1 232 111 mJvCw 1288104 2 1 2 1 232 222 V.420001 iv V.840002 iv
- 15. 15 Series and parallel capacitors • A equivalent capacitance of N parallel-connected capacitors is the sum of the individual capacitors. Ceq = C1 + C2 + C3 + … + Cn. • The equivalent capacitance of series-connected capacitors is the reciprocal of the sum of the reciprocal of the individual capacitors. • For n = 2, 21 21 21 111 CC CC C CCC eq eq
- 16. 16 Example • Find the equivalent capacitance seen between terminal a and b of the circuit. Ceq a b 20F 5F 6F20F 60F
- 17. 17 Solution • 20F and 5F are in series, their equivalent capacitance is • This 4F is parallel with the 6F and 20F capacitors, their combined capacitance is 4+6+20 = 30F. • This 30 F is in series with 60 F capacitor. Hence the equivalent capacitance is .4 520 520 F .20 3060 3060 FCeq
- 18. 18 Inductors • An inductor is a passive element designed to store energy in its magnetic field. • An inductor consists of a coil of conducting wire. • If current is allowed to pass through an inductor, it is found that the voltage across the inductor is directly proportional to the time rate of change of the current. where L is the inductance. dt di Lv
- 19. 19 Inductance • The unit of inductance is the Henry (H). • Inductance is the property whereby an inductor exhibits opposition to the change of current flowing through it measured in Henry (H). • The inductance of an inductor depends on its physical dimension and construction. • For solenoid where N is the number of turns, l is the length, A is the cross- sectional area, and is the permeability of the core. l AN L 2
- 20. 20 Circuit symbol for inductors (a) air-core (b) Iron-core (c) Variable
- 21. 21 Current-voltage relationship for inductor • The current-voltage relationship is obtained from where i(to) is the current at time to. t t o t o tidttv L i dttv L i vdt L di )()( 1 )( 1 1
- 22. 22 Power delivered to the inductor • Power delivered is • Energy stored is i dt di Lvip 2 2 1 LiidiL idt dt di Lpdtw i tt
- 23. 23 Properties of inductor 1. Voltage across an inductor is zero when the current is constant. An inductor acts like a short circuit to dc. 2. Its opposition to the change in current flowing through it. The current through an inductor cannot change instantaneously. 3. Ideal inductor does not dissipate energy. 4. Real inductor has winding resistance and capacitance.
- 24. 24 Example The current through a 0.1-H inductor is Find the voltage across the inductor and the energy stored in it. Solution Voltage Energy stored A.10)( 5t teti V.)51( )5( 10 1.0 5 55 5 t tt t et ete dt ted v J.5t)10)(1.0( 2 1 10225 tt etew
- 25. 25 Example Consider the circuit as shown, under dc condition, find (a) I, vc and iL,, (b) the energy stored in the capacitor and inductor.
- 26. 26 Solution (a) Under dc condition, replace the capacitor with an open circuit and inductor with a short circuit. i = iL = 12/(1+5) = 2 A. vC = 5 i = 5x2 = 10V (a) Energy in capacitor is Energy in inductor is J.50)10)(1( 2 1 2 Cw J.4)2)(2( 2 1 2 Lw
- 27. 27 Series Inductors • Consider a series of N inductors, the equivalent inductor • The equivalent inductance of series-connected inductors is the sum of the individual inductors. Neq LLLLL ...321
- 28. 28 Parallel Inductors • Consider a parallel–connection of N inductors, the equivalent inductor • The equivalent inductance of parallel inductors is the reciprocal of the sum of the reciprocal of the individual inductors. Neq LLLLL 1 ... 1111 321
- 29. 29 Two inductors in parallel • For two inductors in parallel combination, Or • The combination is the same way as resistors in parallel. 21 111 LLLeq . 21 21 LL LL Leq
- 30. 30 Example Find the equivalent inductance of the circuit.
- 31. 31 Solution • The 10-H, 12-H and 20-H inductors are in series, combining them gives 42-H inductance. • This 42-H inductor is in parallel to 7-H inductor so that they are combined, to give • This 6-H inductor is in series with 4-H and 8-H inductors. Hence Leq = 4+6+8 = 18H. .6 427 427 H
- 32. 32 Example For the circiut shown, If i2(0) = -1 mA, Find: (a) i1(o), (b) v(t), v1(t) and v2(t); (c) i1(t) and i2(t). .)2(4)( 10 mAeti t
- 33. 33 Solution (a) (b) Equivalent inductance is Leq = 2 + 4║12 = 2+3 = 5H .5)1(4)0()0()0( .4)12(4)0( 21 2121 mAiii iiiiii mAmAi mV.200)10)(1(45 ))2(4( 5)( 1010 10 tt t eq ee dt ed dt di Ltv
- 34. 34 Solution Since v = v1 +v2. v2.= v - v1 = 120e-10t mV. (c) Current i1 is obtained as similarly mV.80)10)(1)(4(22)( 1010 1 tt ee dt di tv .385335 0 -3e mA5 4 120 )0( 4 1 )( 101010t- 0 0 10 121 mAeemA t dteidtvti tt t t t .111 0 -e mA1 12 120 )0( 12 1 )( 101010t- 0 0 10 222 mAeemA t dteidtvti tt t t t
- 35. 35 ***AC current
- 36. 36 )2cos( 2 1 )cos( 2 1 )( ivmmivmm tIVIVtp • Instantaneous power changes with time and is therefore difficult to measure. The average power is more convenient to measure. • Wattmeter is measuring average power. Average power (watts) – average power of the instantaneous power over the period. The average power is given as: T avg dttp T P 0 )( 1 Average power
- 37. 37 Average Power )cos( 2 1 ivmmavg IVP )2cos( 2 1 )cos( 2 1 )( ivmmivmm tIVIVtp T avg dttp T P 0 )( 1 From the, It can be derived that the average power: (constant) (sinusoid) Since, the average of constant is constant and the average of sinusoid = 0. So, dttIV T dtIV T P ivmm T ivmm T avg )2cos( 2 11 )cos( 2 11 00
- 38. 38 Average power of purely resistive load, R 090cos 2 1 o mmavg IVP For purely resistive load, v = i, so that: Average power of reactive circuit: C, L # The resistive load absorb power all the time. For purely reactive elements, v - i = 90o, so that: RRIIVP mmmavg 22 |I| 2 1 2 1 2 1 # The purely reactive load (L or C) absorbs zero power.
- 39. 39 • Effective value determine the effectiveness of voltage or current source in delivering power to the load. • For any periodic function x(t) in general, the rms value is given by • For a sinusoid i(t) = Im cos t Similarly for v(t) = Vm cos t T rms dtx T X 0 21 2 cos 1 0 22 m T mrms I dttI T I 2 cos 1 0 22 m T mrms V dttV T V )cos()cos( 2 1 ivrmsrmsivmm IVIVP R V RIP rms rms 2 2 The average power can be written in terms of rms values. The average power absorbed by a resistor, R is, Effective or RMS Power
- 40. 40 The voltage V produced between the terminals of an ac generator fluctuates sinusoidally in time. Why?
- 41. 41 What’s the average voltage in an AC circuit? Average current?
- 42. 42 Does zero average current and voltage imply zero average power? # NO, it depends on your load is R, C or L.
- 43. 43 What power is dissipated in a resistor R connected across an AC voltage source? V = V 0 sin 2p f t I = (V0/R) sin 2p f t = I 0 sin 2p f t P = I0*V 0 sin2 2p f t Pave = I0*V0/2
- 44. 44 ***In this three-phase circuit there is 266 V rms between line 1 and ground. What is the rms voltage between line 2 and 3? VVVV tV ttVVV VVV rms rms 460 3 sin2 2 1 )( )2(cos)(sin2 )]3/2sin()3/4[sin( 2662/ 023 2 1 3 2 2 1 0 023 0 p pp p
- 45. 45 AC vs DC: The battle of the currents
- 46. 46 Example A stereo receiver applies a peak ac voltage of 34 V to a speaker. The speaker behaves approximately as if it has a resistance of 8.0 , as shown. Determine (a) the rms voltage, (b) the rms current, and (c) the average power for this circuit.
- 47. 47 Example
- 48. 48 Example
- 49. 49 In a resistive load, the current and voltage are in phase RC and RL circuit
- 50. 50 In a purely capacitive load, the current leads the voltage by 90º.
- 51. 51 In a purely capacitive load, the current leads the voltage by 90º. )( 1 )/1( 2 cossin cos cos 0 max max maxmax max max reactancecapacitive C X C I tCtC dt dQ I t C Q tV V C C C p CCC XIV
- 52. 52 What is the average power dissipated in the capacitor? On the average, the power is zero and a capacitor uses no energy in an ac circuit. V=V0 sin (2pft) I=I0 sin (2pft + p/2) = I0 cos (2pft) Pave = (I·V)ave = 0 Average power, P = 0 But, Reactive power, Q ≠ 0 c c X V XIQ 2 2
- 53. 53 In a purely inductive circuit, the current lags the voltage by 90º )( 2 cos 2 cos )0(sincos cos cos 0 max max max max maxmax max max reactanceinductiveLX L I tIt L I CCt L dtt L I t dt dI L tV V L L L p p
- 54. 54 In a purely inductive circuit, the current lags the voltage by 90º c c X V XIQ 2 2 For purely inductive load, again Average power, P = 0 But, Reactive power, Q ≠ 0
- 58. 58 Phasors for a series RLC circuit Max or rms: V0 2 = VR 2 + (VL - VC)2 Vrms = IrmsZ VR = IrmsR, VC = IrmsXC, and VL = IrmsXL
- 59. 59 Power factor for a series RLC circuit
- 60. 60 Summary of the AC phasor relations
- 61. 61 Summary of impedance relations = 1/ωC = ωL