1. alternating currents & electromagnetic waves PHY232 – Spring 2007 Jon Pumplin http://www.pa.msu.edu/~pumplin/PHY232 (Ppt courtesy of Remco Zegers)

2. PHY232 - Pumplin - alternating currents and electromagnetic waves 2 Question At t=0, the switch is closed. After that: a) the current slowly increases from I = 0 to I = V/R b) the current slowly decreases from I = V/R to I = 0 c) the current is a constant I = V/R LR V I

3. PHY232 - Pumplin - alternating currents and electromagnetic waves 3 Answer  At t=0, the switch is closed. After that: a) the current slowly increases from I=0 to I=V/R b) the current slowly decreases from I=V/R to I=0 c) the current is a constant I=V/R The coil opposes the flow of current due to self-inductance, so the current cannot immediately become the maximum I=V/R. It will slowly rise to this value (characteristic time Tau = L/R). LR V I

4. PHY232 - Pumplin - alternating currents and electromagnetic waves 4 Alternating current circuits  Previously, we look at DC circuits: the voltage delivered by the source is constant, as on the left.  Now, we look at AC circuits, in which case the source is sinusoidal. A is used in circuits to denote this. R VV R I I

5. PHY232 - Pumplin - alternating currents and electromagnetic waves 5 A circuit with a resistor  The voltage over the resistor is the same as the voltage delivered by the source: V R (t) = V 0 sin  t = V 0 sin(2  ft)  The current through the resistor is: I R (t)= (V 0 /R) sin  t  Since V(t) and I(t) have the same behavior as a function of time, they are said to be ‘in phase’.  V 0 is the maximum voltage  V(t) is the instantaneous voltage   is the angular frequency;  =2  f f: frequency (Hz)  SET YOUR CALCULATOR TO RADIANS WHERE NECESSARY I V(t)=V 0 sin  t R I R (A) V 0 =10 V R=2 Ohm  =1 rad/s

6. PHY232 - Pumplin - alternating currents and electromagnetic waves 6 rms currents/voltages  To understand energy consumption by the circuit, it doesn’t matter what the sign of the current/voltage is. We need the absolute average currents and voltages (root-mean-square values) :  V rms =V max /  2  I rms =I max /  2  The following hold:  V rms =I rms R  V max =I max R I R (A) |I R| (A) |V R |(V) V rms I rms

7. PHY232 - Pumplin - alternating currents and electromagnetic waves 7 power consumption in an AC circuit  We already know for DC P = V I = V 2 /R = I 2 R  For AC circuits with a single resistor: P(t) = V(t) * I(t) = V 0 I 0 (sin  t) 2  Average power consumption: P ave = V rms * I rms = V 2 rms /R = I 2 rms R where V rms = V max /  2) I rms = I max /  2 |I R| (A) |V R |(V) V rms I rms P(W)

8. PHY232 - Pumplin - alternating currents and electromagnetic waves 8 vector representation time (s) V0V0 -V 0 V The voltage or current as a function of time can be described by the projection of a vector rotating with constant angular velocity on one of the axes (x or y). =t=t

9. PHY232 - Pumplin - alternating currents and electromagnetic waves 9 AC circuit with a single capacitor I V(t)=V 0 sin  t C V c = V 0 sin  t Q c = CV c = C V 0 sin  t I c =  Q c /  t =  C V 0 cos  t So, the current peaks ahead of the voltage: There is a difference in phase of  /2 (90 0 ). I (A) Why? When there is not much charge on the capacitor it readily accepts more and current easily flows. However, the E-field and potential between the plates increase and consequently it becomes more difficult for current to flow and the current decreases. If the potential over C is maximum, the current is zero.

10. PHY232 - Pumplin - alternating currents and electromagnetic waves 10 Capacitive circuit - continued I (A) Note: I max =  C V 0 For a resistor we have I = V 0 /R so ‘1/  C’ is similar to ‘R’ And we write: I=V/X c with X c = 1/  C the capacitive reactance Units of X c are Ohms. The capacitive reactance acts like a resistance in this circuit. I V(t) = V 0 sin  t C

11. PHY232 - Pumplin - alternating currents and electromagnetic waves 11 Power consumption in a capacitive circuit There is no power consumption in a purely capacitive circuit: Energy (1/2 C V 2 ) gets stored when the (absolute) voltage over the capacitor is increasing, and released when it is decreasing. P ave = 0 for a purely capacitive circuit

12. PHY232 - Pumplin - alternating currents and electromagnetic waves 12 AC circuit with a single inductor I V(t) = V 0 sin  t L V L = V 0 sin  t = L  I/  t I = -(V 0 /(  L)) cos  t (no proof here: you need calculus…) the current peaks later in time than the voltage: there is a difference in phase of  /2 (90 0 ) I (A) Why? As the potential over the inductor rises, the magnetic flux produces a current that opposes the original current. The voltage across the inductor peaks when the current is just beginning to rise.

13. PHY232 - Pumplin - alternating currents and electromagnetic waves 13 Inductive circuit - continued Note: I max = V 0 /(  L) For a resistor we have I = V 0 /R so ‘  L’ is similar to ‘R’ And we write: I = V/X L with X L =  L the inductive reactance Units of X L are Ohms. The inductive reactance acts as a resistance in this circuit. I L (A) I V(t) = V 0 sin  t L I(A)

14. PHY232 - Pumplin - alternating currents and electromagnetic waves 14 Power consumption in an inductive circuit There is no power consumption in a purely inductive circuit: Energy (1/2 L I 2 ) gets stored when the (absolute) current through the inductor is increasing, and released when it is decreasing. P ave = 0 for a purely inductive circuit

15. PHY232 - Pumplin - alternating currents and electromagnetic waves 15 Reactance The inductive reactance (and capacitive reactance) are like the resistance of a normal resistor, in that you can calculate the current, given the voltage, using I = V/X L (or I = V/X C ). This works for the Maximum values, or for the RMS average values. But I and V are “out of phase”, so the maxima occur at different times.

16. PHY232 - Pumplin - alternating currents and electromagnetic waves 16 Combining the three: the LRC circuit  Things to keep in mind when analyzing this system:  1) The current in the system has the same value everywhere I = I 0 sin(  t-  )  2) The voltage over all three components is equal to the source voltage at any point in time: V(t) = V 0 sin(  t) I V(t)=V 0 sin  t LCR

17. PHY232 - Pumplin - alternating currents and electromagnetic waves 17 An LRC circuit  For the resistor: V R = I R and V R and I are in phase  For the capacitor: V c = I X c (“V c lags I by 90 0”)  For the inductor: V L = I X L (“V L leads I by 90 0”)  at any instant: V L +V c +V R =V 0 sin(  t). But the maximum values of V L +V c +V R do NOT add up to V 0 because they have their maxima at different times. VRVR I VCVC VLVL I V(t)=V 0 sin  t LCR

18. PHY232 - Pumplin - alternating currents and electromagnetic waves 18 impedance  Define X = X L -X c = reactance of RLC circuit  Define Z =  [R 2 +(X L -X c ) 2 ]=  [R 2 +X 2 ] = impedance of RLC cir  Then V tot = I Z looks like Ohms law! I V(t)=V 0 sin  t LCR

19. PHY232 - Pumplin - alternating currents and electromagnetic waves 19 Resonance  If the maximum voltage over the capacitor equals the maximum voltage over the inductor, the difference in phase between the voltage over the whole circuit and the voltage over the resistor is:  a) 0 0  b)45 0  c)90 0  d)180 0 In this case, X L

20. PHY232 - Pumplin - alternating currents and electromagnetic waves 20 Power consumption by an LRC circuit  Even though the capacitor and inductor do not consume energy on the average, they affect the power consumption since the phase between current and voltage is modified.  P = I 2 rms R

21. PHY232 - Pumplin - alternating currents and electromagnetic waves 21 Example  questions:  what is the angular frequency of the system?what are the inductive and capacitive reactances?  what is the impedance, what is the phase angle   what is the maximum current and peak voltages over each element  compare the algebraic sum of peak voltages with V 0. Does this make sense?  what are the instantaneous voltages and rms voltages over each element?  what is power consumed by each element and total power consumption I V(t)=V 0 sin  t LCR Given: R=250 Ohm L=0.6 H C=3.5  F f=60 Hz V 0 =150 V

22. PHY232 - Pumplin - alternating currents and electromagnetic waves 22 answers  a) angular frequency  of the system?   =2  f=2  60=377 rad/s  b) Reactances?  X C =1/  C=1/(377 x 3.5x10 -6 )=758 Ohm  X L =  L=377x0.6=226 Ohm  c) Impedance and phase angle  Z=  [R 2 +(X L -X c ) 2 ]=  [250 2 +(226-758) 2 ]=588 Ohm   =tan -1 [(X L -X C )/R)=tan -1 [(226-758)/250]=-64.8 0 (or –1.13 rad)  d) Maximum current and maximum component voltages:  I max =V max /Z=150/588=0.255 A  V R =I max R=0.255x250=63.8 V  V C =I max X C =0.255x758=193 V  V L =I max X L =0.255x266=57.6 V  Sum: V R +V C +V L =314 V. This is larger than the maximum voltage delivered by the source (150 V). This makes sense because the relevant sum is not algebraic: each of the voltages are vectors with different phases. Given: R=250 Ohm L=0.6 H C=3.5  F f=60 Hz V 0 =150 V

23. PHY232 - Pumplin - alternating currents and electromagnetic waves 23 answers  f) instantaneous voltages over each element (V tot has 0 phase)?  start with the driving voltage V=V 0 sin  t=V tot  V R (t)=63.8sin(  t+1.13) (note the phase relative to V tot )  V C (t)=193sin(  t-0.44) phase angle : 1.13-  /2=-0.44  V L (t)=57.6sin(  t+2.7) phase angle : 1.13+  /2=2.7  rms voltages over each element?  V R, rms =63.8/  2=45.1 V  V C,rms =193/  2=136 V  V L,rms =57.6/  2=40.7 V  I max =V max /Z=0.255 A  V R =I max R=63.8 V  V C =I max X C =193 V  V L =I max X L =57.6 V   =-64.8 0 (or –1.13 rad)  V tot =150 V

24. PHY232 - Pumplin - alternating currents and electromagnetic waves 24 answers  g) power consumed by each element and total power consumed?  P C =P L =0 no energy is consumed by the capacitor or inductor  P R =I rms 2 R=(I max /  2) 2 R=0.255 2 R/2=0.255 2 *250/2)=8.13 W  or: P R =V rms 2 /R=(45.1) 2 /250=8.13 W (don’t use V rms =V 0 /  2!!)  or: P R =V rms I rms cos  =(150/  2)(0.255/  2)cos(-64.8 0 )=8.13 W  total power consumed=power consumed by resistor!

25. PHY232 - Pumplin - alternating currents and electromagnetic waves 25 LRC circuits: an overview  Reactance of capacitor: X c = 1/  C  Reactance of inductor: X L =  L  Current through circuit: same for all components  ‘Ohms’ law for LRC circuit: V tot =I Z  Impedance: Z=  [R 2 +(X L -X c ) 2 ]  phase angle between current and source voltage: tan  =(|V L | -|V c | )/V R =(X L -X c )/R  Power consumed (by resistor only): P=I 2 rms R=I rms V R P=V rms I rms cos   V R =I max R in phase with current I, out of phase by  with V tot  V C =I max X C behind by 90 0 relative to I (and V R )  V L =I max X L ahead of 90 0 relative to I (and V R )

26. PHY232 - Pumplin - alternating currents and electromagnetic waves 26 Question  The sum of maximum voltages over the resistor, capacitor and inductor in an LRC circuit cannot be higher than the maximum voltage delivered by the source since it violates Kirchhoff’s 2 nd rule (sum of voltage gains equals the sum of voltage drops).  a) true  b) false answer: false The maximum voltages in each component are not achieved at the same time!

27. PHY232 - Pumplin - alternating currents and electromagnetic waves 27 Resonances in an RLC circuit  If we chance the (angular) frequency the reactances will change since:  Reactance of capacitor: X c = 1/  C  Reactance of inductor: X L =  L  Consequently, the impedance Z=  [R 2 +(X L -X c ) 2 ] changes  Since I=V tot /Z, the current through the circuit changes  If X L =X C (I.e. 1/  C=  L or  2 =1/LC), Z is minimal, I is maximum)   =  (1/LC) is the resonance angular frequency  At the resonance frequency  =0

28. PHY232 - Pumplin - alternating currents and electromagnetic waves 28 example Given: R=250 Ohm L=0.6 H C=3.5  F f=60 Hz V 0 =150 V Using the same given parameters as the earlier problem, what is the resonance frequency?  =  (1/LC)=690 rad/s f=  /2  =110 Hz

29. PHY232 - Pumplin - alternating currents and electromagnetic waves 29 question  An LRC circuit has R=50 Ohm, L=0.5 H and C=5x10 -3 F. An AC source with V max =50V is used. If the resistance is replaced with one that has R=100 Ohm and the V max of the source is increased to 100V, the resonance frequency will:  a) increase  b)decrease  c) remain the same answer c) the resonance frequency only depends on L and C

30. PHY232 - Pumplin - alternating currents and electromagnetic waves 30 transformers transformers are used to convert voltages to lower/higher levels

31. PHY232 - Pumplin - alternating currents and electromagnetic waves 31 transformers VpVp VsVs primary circuit with N p loops in coil secondary circuit with N s loops in coil iron core If an AC current is applied to the primary circuit: V p =-N p  B /  t The magnetic flux is contained in the iron and the changing flux acts in the secondary coil also: V s =-N s  B /  t Therefore: V s =(N s /N p )V p if N s <N p then V s <V p A perfect transformer is a pure inductor (no resistance), so no power loss: P p =P S and V p I p =V s I s ; if N s I p

32. PHY232 - Pumplin - alternating currents and electromagnetic waves 32 question a transformer is used to bring down the high-voltage delivered by a powerline (10 kV) to 120 V. If the primary coil has 10000 windings, a) how many are there in the secondary coil? b) If the current in the powerline is 0.1 A, what is the maximum current at 120 V? a)V s =(N s /N p )V p or N s =(V s /V p )N p = 120 windings b)V p I p =V s I s so I s =V p I p /V s =8.33 A

33. PHY232 - Pumplin - alternating currents and electromagnetic waves 33 question  Is it more economical to transmit power from the power station to homes at high voltage or low voltage?  a) high voltage  b) low voltage answer: high voltage If the voltage is high, the current is low If the current is low, the voltage drop over the power line (with resistance R) is low, and thus the power dissipated in the line ([  V] 2 /R=I 2 R) also low

34. PHY232 - Pumplin - alternating currents and electromagnetic waves 34 electromagnetic waves  James Maxwell formalized the basic equations governing electricity and magnetism ~1870:  Coulomb’s law  Magnetic force  Ampere’s Law (electric currents make magnetic fields)  Faraday’s law (magnetic fields make electric currents)  Since changing fields electric fields produce magnetic fields and vice versa, he concluded:  electricity and magnetism are two aspects of the same phenomenon. They are unified under one set of laws: the laws of electromagnetism

35. PHY232 - Pumplin - alternating currents and electromagnetic waves 35 electromagnetic waves Maxwell found that electric and magnetic waves travel together through space with a velocity of 1/  (  0  0 ) v=1/  (  0  0 )=1/  (4  x10 -7 x 8.85x10 -12 )=2.998x10 8 m/s which is just the speed of light (c)

36. PHY232 - Pumplin - alternating currents and electromagnetic waves 36 electromagnetic waves can be used to broadcast…  Consider the experiment performed by Herz (1888) I Herz made an RLC circuit with L=2.5 nH, C=1.0nF The resonance frequency is  =  (1/LC)=6.32x10 8 rad/s f=  /2  =100 MHz. Recall that the wavelength of waves =v/f=c/f=3x10 8 /100x10 6 =3.0 m wavelength: =v/f

37. PHY232 - Pumplin - alternating currents and electromagnetic waves 37 He then constructed an antenna  charges and currents vary sinusoidally in the primary and secondary circuits. The charges in the two branches also oscillate at the same frequency f I dipole antenna

38. PHY232 - Pumplin - alternating currents and electromagnetic waves 38 producing the electric field wave antenna ++++++ ---------- ++++++ ----------

39. PHY232 - Pumplin - alternating currents and electromagnetic waves 39 producing the magnetic field wave antenna ++++++ ---------- I I ++++++ ---------- I I E and B are in phase and E=cB with c: speed of light The power/m 2 =0.5E max B max /  0 The energy in the wave is shared between the E-field and the B-field

40. PHY232 - Pumplin - alternating currents and electromagnetic waves 40 question Can a single wire connected to the + and – poles of a DC battery act as a transmitter of electromagnetic waves? a)yes b)no answer: no: there is no varying current and hence no wave can be made.

41. PHY232 - Pumplin - alternating currents and electromagnetic waves 41 c=f