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Transcript
Your Comments
I work as an audio technician, and I've seen Q before as a quantity you adjust in variable
equalizers! If you want to eliminate a broad spectrum of sound centered around a certain
frequency you dial back the Q value; and vice-versa for cutting out a very specific frequency. So
in reality I'm just dialing back the resistance in an LCR circuit!
Can you explain why power is stepped up for transmission? My old man tried to explain it to
me once but it's been quite some time since his days as an undergrad.
I keep falling asleep during lecture whenever you give us permission and then I feel like I
miss so much when I go to do the homework. Please don't give us permission to fall asleep
anymore.
In lecture, do you think you could give a more qualitative representation of relative
voltages and currents at resonance? If I can reason a rough estimate of how a circuit
works without applying equations, I feel I get a much better grasp of the concept.
I feel that this lecture on transformers would be more exciting if it were directed by Michael
Bay. At least try and fit an explosion or giant robot or something into the lecture.
Wow this was ridiculous. Just lots of equations being thrown at me. Thank you.
something different needs to happen for this unit. I have always been throughly impressed by
how much the Physics department cares about our understanding of the material. You do a
phenomenal job, every week, with this well thought out plan for our better understanding. this
set of lessons, however, with all the phases and everything, is still just really really confusing.
I think that something special should happen in discussion or something (maybe it will, I have
it tomorrow morning)
Nice work on hour exam 2
Average score 75%
Electricity & Magnetism Lecture 21, Slide 2
Physics 212
Lecture 21
Looks intimidating, but isn’t bad!
Electricity & Magnetism Lecture 21, Slide 4
Peak AC Problems
“Ohms” Law for each element
NOTE: Good for PEAK values only)
Vgen
= Imax Z
VResistor = Imax R
Vinductor = Imax XL
VCapacitor = Imax XC
Typical Problem
Z = R2   X L  X C  2
X L = L
XC =
1
XC =
= 100 
C
L
R
1
C
A generator with peak voltage 15 volts and angular frequency 25 rad/sec is
connected in series with an 8 Henry inductor, a 0.4 mF capacitor and a 50 ohm
resistor. What is the peak current through the circuit?
X L = L = 200 
C
XL
Z = R 2   X L  X C  2 = 122 
I max =
Vgen
Z
R
= 0.13 A
XC
Peak AC Problems
“Ohms” Law for each element
NOTE: Good for PEAK values only)
Vgen
= Imax Z
VResistor = Imax R
Vinductor = Imax XL
VCapacitor = Imax XC
Typical Problem
Z = R2   X L  X C  2
C
X L = L
XC =
R
1
C
A generator with peak voltage 15 volts and angular frequency 25 rad/sec is
connected in series with an 8 Henry inductor, a 0.4 mF capacitor and a 50 ohm
resistor. What is the peak current through the circuit?
XL
Which element has the largest peak voltage across it?
A) Generator
E) All the same.
D) Capacitor
Vmax = I max X
X L = L = 200 
XC =
B) Inductor
C) Resistor
L
R
XC
1
= 100 
C
Z = R 2   X L  X C  2 = 122 
I max =
Vgen
Z
= 0.13 A
Peak AC Problems
“Ohms” Law for each element
NOTE: Good for PEAK values only)
Vgen
= Imax Z
VResistor = Imax R
Vinductor = Imax XL
VCapacitor = Imax XC
Typical Problem
Z = R2   X L  X C  2
C
X L = L
XC =
L
R
1
C
A generator with peak voltage 15 volts and angular frequency 25 rad/sec is
connected in series with an 8 Henry inductor, a 0.4 mF capacitor and a 50 ohm
resistor. What is the peak current through the circuit?
XL
XL
What happens to the impedance if we decrease the angular
frequency to 20 rad/sec?
Z25
Z20
A) Z increases
C) Z decreases
R
R
B) Z remains the same
(XL  XC): (200  100) -> (160  125)
XC
XC
Resonance
Light-bulb Demo
Resonance
Frequency at which voltage across inductor and capacitor cancel
R is independent of 
XL increases with 
X L = L
Z = R at resonance
XC increases with 1/
1
XC =
C
Z = R  ( X L  XC )
2
Z
2
XL
0
is minimum at resonance
Resonance: XL = XC
0 =
1
LC
XC
R
Off Resonance
Z
In general
U
Q  2 max
DU
Umax = max energy stored
DU = energy dissipated
in one cycle at resonance
Off Resonance
CheckPoint 1a
Imax XL
Consider two RLC circuits with identical generators and resistors.
Both circuits are driven at the resonant frequency. Circuit II has twice
the inductance and 1/2 the capacitance of circuit I as shown above.
Compare the peak voltage across the resistor in the two circuits
A. VI > VII
B. VI = VII
C. VI < VII
Resonance: XL = XC
Z =R
Same since R doesn't change
Imax XL
Imax R
Imax R
Imax XC
Case 1
Imax XC
Case 2
CheckPoint 1b
Imax XL
Consider two RLC circuits with identical generators and resistors.
Both circuits are driven at the resonant frequency. Circuit II has
twice the inductance and 1/2 the capacitance of circuit I as shown
above.
Compare the peak voltage across the inductor in the
two circuits
A. VI > VII
B. VI = VII
Voltage in second circuit will
be twice that of the first
because of the 2L compared
to L.
Imax XL
Imax R
C. VI < VII
Imax R
Imax XC
Case 1
Imax XC
Case 2
CheckPoint 1c
Imax XL
Consider two RLC circuits with identical generators and resistors.
Both circuits are driven at the resonant frequency. Circuit II has
twice the inductance and 1/2 the capacitance of circuit I as shown
above.
Compare the peak voltage across the inductor in the
two circuits
A. VI > VII
B. VI = VII
Imax XL
Imax R
C. VI < VII
Imax R
The peak voltage will be
greater in circuit 2 because
the value of XC doubles.
Imax XC
Case 1
Imax XC
Case 2
CheckPoint 1D
Imax XL
Consider two RLC circuits with identical generators and resistors.
Both circuits are driven at the resonant frequency. Circuit II has
twice the inductance and 1/2 the capacitance of circuit I as shown
above.
At
the resonant frequency, which of the following is true?
Imax XL
Imax R
A. Current leads voltage across the generator
B. Current lags voltage across the generator
C. Current is in phase with voltage across the generator
Imax R
The voltage across the inductor
and the capacitor are equal
when at resonant frequency, so
there is no lag or lead.
Imax XC
Case 1
Imax XC
Case 2
Power
P = IV instantaneous always true


Difficult for Generator, Inductor and Capacitor because of phase
Resistor I,V are always in phase!
P = IV
= I2 R
C
L
Average Power
R
Inductor and Capacitor = 0 ( < sin(t) cos(t) > = 0 )
Resistor
<I 2R> = <I 2 > R = ½ I 2peak R
RMS = Root Mean Square
Ipeak = Irms sqrt(2)
< I 2 R > = Irms2 R
Power Line Calculation
If you want to deliver 1,500 Watts at 100 Volts over transmission lines w/
resistance of 5 Ohms. How much power is lost in the lines?


Current Delivered: I = P/V = 15 Amps
Loss = IV (on line) = I2 R = 15*15 * 5 = 1,125 Watts!
If you deliver 1,500 Watts at 10,000 Volts over the same transmission lines.
How much power is lost?


Current Delivered: I = P/V = .15 Amps
Loss = IV (on line) = I 2R = 0.125 Watts
DEMO
Transformers
Application of Faraday’s Law


Changing EMF in Primary creates changing flux
Changing flux, creates EMF in secondary
V p Vs
=
N p Ns
Efficient method to change voltage for AC.
Power Transmission Loss = I 2R
Power electronics
Demo
Follow-Up from Last Lecture
Consider the harmonically driven series LCR circuit shown.
Vmax = 100 V
Imax = 2 mA
VCmax = 113 V (= 80 sqrt(2))
The current leads generator voltage by 45o (cos = sin = 1/sqrt(2))
L and R are unknown.
C
V
L
R
How should we change  to bring circuit to resonance?
A) decrease 
Original 
f
B) increase 
At resonance
(0)
C) Not enough info
At resonance
XL = XC
XL increases
XC decreases
 increases
More Follow-Up
Consider the harmonically driven series LCR circuit shown.
Vmax = 100 V
Imax = 2 mA
X C = 40 2 k
VCmax = 113 V (= 80 sqrt(2))
The current leads generator voltage by 45o (cos = sin = 1/sqrt(2))
L and R are unknown.
C
V
R
R = 25 2 k
By what factor should we increase  to bring circuit to resonance?
i.e. if 0 = f, what is f?
A) f = 2
If  is
increased by a
factor of f:
At resonance
XL = XC
B) f = 2 2
X L = 15 2 k
8
D) f =
5
8
C) f =
3
X L  f 15 2
XL increases by factor of f
XC decreases by factor of f
40
15 f =
f
L
X C  1 / f   40 2
40
f =
15
2
8
f =
3
Current Follow-Up
C
Consider the harmonically driven series LCR circuit shown.
Vmax = 100 V
Imax = 2 mA
X C = 40 2 k
VCmax = 113 V (= 80 sqrt(2))
The current leads generator voltage by 45o (cos = sin = 1/sqrt(2))
L and R are unknown.
What is the maximum current at resonance ( Imax(0) )
V
L
R
R = 25 2 k
X L = 15 2 k
0 =
A) I max 0  = 2 mA
At resonance
XL = XC
B) I max 0  = 2 2 mA
Z=R
C) I max 0  =
Vmax
100
I max 0  =
=
= 2 2 mA
R
25 2
8

3
8
mA
3
Phasor Follow-Up
Consider the harmonically driven series LCR circuit shown.
Vmax = 100 V
Imax = 2 mA
VCmax = 113 V (= 80 sqrt(2))
The current leads generator voltage by 45o (cos = sin = 1/sqrt(2))
L and R are unknown.
C
V
L
R
R = 25 2 k
What does the phasor diagram look like at t = 0? (assume V = Vmaxsint)
X L = 15 2 k
A)
X
B)
C)
X
D)
V = Vmax sint -> V is horizontal at t = 0 (V = 0)
   
V = VL  VC  VR
VL < VC if current leads generator voltage
X