Download Lecture 29 Chapter 33 EM Oscillations and AC

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
page
16
page
17
page
18
page
19
page
20
page
21
page
22
Document related concepts

Multimeter wikipedia , lookup

Schmitt trigger wikipedia , lookup

Phase-locked loop wikipedia , lookup

Index of electronics articles wikipedia , lookup

Operational amplifier wikipedia , lookup

Power MOSFET wikipedia , lookup

Valve RF amplifier wikipedia , lookup

TRIAC wikipedia , lookup

Switched-mode power supply wikipedia , lookup

Resistive opto-isolator wikipedia , lookup

Power electronics wikipedia , lookup

Ohm's law wikipedia , lookup

Opto-isolator wikipedia , lookup

Surge protector wikipedia , lookup

Current source wikipedia , lookup

RLC circuit wikipedia , lookup

Current mirror wikipedia , lookup

Wien bridge oscillator wikipedia , lookup

Rectiverter wikipedia , lookup

Transcript 
Lecture 29
Chapter 33
EM Oscillations and AC
Review
• RL and RC circuits
– Charge, current, and potential
grow and decay exponentially
• LC circuit
– Charge, current, and potential
grow and decay sinusoidally –
electromagnetic oscillations
– Total electromagnetic energy is
Li 2 q 2
U = UB + UE =
+
2
2C
Review
dU
=0
– Total energy conserved dt
• Ideal LC circuit
– Solved differential equation to find
q = Q cos(ωt + φ )
i = − I sin(ωt + φ )
1
LC
ω=
– Substituting q and i into energy equations
U
E
Q2
=
cos
2C
2
(ω t + φ )
U
B
Q2
=
sin
2C
U = U B + U E = Q 2 / 2C
2
(ω t + φ )
Review
• RLC circuit
– Energy is no longer conserved,
becomes thermal energy in resistor
– Oscillations are damped
– Solved differential equation to find
− Rt / 2 L
q = Qe
dU
= −i 2 R
dt
cos(ω ′t + φ )
2
2
′
ω = ω − ( R / 2 L)
ω=
If R is very small
1
LC
ω′ = ω
– Energy decreases as
Q 2 − Rt / L
UE =
e
cos2 (ω ′t + φ )
2C
Q 2 − Rt / L
Utot =
e
2C
EM Oscillations (23)
• LC and RLC circuits with no external emf
– Free oscillations with natural
frequency, ω
• Add external emf (e.g. ac
to RLC circuit
– Oscillations said to be
or forced
– Oscillations occur at driving
frequency, ωd
– When ωd = ω, called resonance,
current amplitude, I, is maximum
angular
ω=
1
LC
generator)
driven
angular
the
EM Oscillations (24)
• ac generator – mechanically
turn loop in B field, induces a
current and therefore an emf
• Used Faraday’s law to find emf
dΦ B
E = −N
= NBA ω sin ωt
dt
E max = NBA ω
E = E max sin ωt
E
t
EM Oscillations (25)
E = E m sin ω d t
– Driving angular frequency, ωd
is equal to angular speed that
loop rotates in B field
– The phase of the emf is ωd t
– Amplitude is Em where m stands
for maximum
• Current of ac generator where φ
corresponds to phase difference
between the current and emf
i = I sin (ω d t − φ )
ω d = 2πf d
• I is amplitude
• Minus sign historical
EM Oscillations (26)
• Purely resistive load
• Apply loop rule
E − vR = 0
• Using
E = E m sin ω d t
• Substitute
vR = Em sin ω d t
• Amplitude across
resistor is same as
across emf
E m = VR
• Rewrite vR as
vR = VR sin ω d t
EM Oscillations (27)
• Use definition of
resistance to find iR
v R = V R sin ω d t
VR
R=
IR
vR VR
iR =
=
sin ω d t
R
R
• Voltage and current are
functions of sin(ωdt) with
φ = 0 so are in phase
• No damping of vR and iR ,
generator supplies energy
EM Oscillations (28)
• Compare iR to i for emf
vR VR
iR =
= sin ω d t
R
R
iemf = iR = I R sin(ωd t − φ )
• For purely resistive load the
phase constant φ = 0
• Voltage amplitude is related
to current amplitude
VR = I R R
VR
IR =
R
VR = I R R
EM Oscillations (29)
• Purely capacitive load
• Apply loop rule
E − vC = 0
• Using
E = E m sin ω d t
• Substitute
vC = Em sin ω d t
• Amplitude across
capacitor is same
as across emf
E m = VC
• Rewrite vC as
vC = VC sin ω d t
EM Oscillations (30)
• Use definition of
capacitance
qC = CvC
qC = Cv C = CV C sin ω d t
• Use definition of current
and differentiate
dq
i=
dt
dq C
iC =
= ω d CV C cos ω d t
dt
• Replace cosine term
with a phase-shifted
sine term
cosωd t = sin(ωd t + 90°)
EM Oscillations (31)
• Compare vC and iC
of capacitor
vC = VC sin ω d t
iC = ωdCVC sin(ωd t + 90°)
• Voltage and current are
out of phase by 90°
• Current leads voltage
– Current reaches its max
before voltage does by a
quarter cycle or T/4
EM Oscillations (32)
• Now compare currents
iC = ωd CVC sin(ωd t + 90°) iemf = iC = I C sin(ωd t − φ )
• For purely capacitive load phase φ = -90°
• VC amplitude is related to IC amplitude
1
I C = ω d CVC VC = I C ω C = I C X C
d
• XC is the capacitive reactance and has SI
unit of ohm, Ω just like resistance R
VC = I C X C
1
XC =
ωd C
EM Oscillations (33)
• Purely inductive load
• Apply loop rule
E − vL = 0
• Using
E = E m sin ω d t
• Substitute
vL = Em sin ω d t
• Amplitude across
inductor is same
as across emf
E m = VL
• Rewrite vL as
vL = VL sin ω d t
EM Oscillations (34)
• Self-induced emf across
an inductor is
di
• Relate
E L = vL = L
dt
di
v L = VL sin ω d t = L
dt
di
VL
=
sin ω d t
dt
L
• Want current so integrate
 VL 
VL
 cosωd t
iL = ∫ diL = ∫ sinωd tdt = −
L
 ωd L 
EM Oscillations (35)
• Replace -cosine with a
phase-shifted sine term
− cos ω d t = sin(ω d t − 90°)
 VL 
VL


iL = − 
cos ω d t =
sin(ω d t − 90°)

ωd L
 ωd L 
• Compare iL to vL
• iL and vL are 90° out
of phase
• Current lags voltage
– iL reaches max after vL
by a quarter cycle or T/4
vL = VL sin ω d t
EM Oscillations (36)
• Now compare currents
VL
iL =
sin( ω d t − 90 ° )
ωd L
iemf = iL = I L sin (ωd t − φ )
• For purely inductive load phase φ = +90°
• VL amplitude is related to IL amplitude
VL
IL =
V
=
I
ω
L
=
I
X
L
L
d
L
L
ωd L
• XL is the inductive reactance and has SI unit
of ohm, Ω just like resistance R
VL = I L X L
X L = ωd L
EM Oscillations (37)
Element
Resistor
Capacito
r
Inductor
Reactance Phase of Phase Amplitude
/
Current angle φ Relation
Resistance
VR=IRR
R
In phase
0°
XC= 1/ωdC Leads
vC (ICE)
XL=ωdL Lags vL
(ELI)
-90°
VC=ICXC
+90°
VL=ILXL
• ELI the ICE man
– Voltage or emf (E) before current (I) in an inductor (L)
– Current (I) before voltage or emf (E) in capacitor (C)
EM Oscillations (38)
• Checkpoints #3, 5, & 6 – If the driving
frequency, ωd , in a circuit is increased does the
amplitude voltage and amplitude current
increase, decrease or remain the same?
• For purely resistive circuit
• From loop rule VR = Em
• So amplitude voltage, VL stays the same
• IR also stays the same VR
IR =
only depends on R
R
IR
EM Oscillations (39)
• Checkpoints #3, 5, & 6 – If the driving
frequency, ωd , in a circuit is increased does the
amplitude voltage and amplitude current
increase, decrease or remain the same?
• For purely capacitive circuit
• From loop rule Vc = Em
• So amplitude voltage, VC stays the same
• IC depends on XC which depends on ωd by
• So IC increases
V
IC =
C
XC
= ω d CVC
EM Oscillations (40)
• Checkpoints #3, 5, & 6 – If the driving
frequency, ωd , in a circuit is increased does the
amplitude voltage and amplitude current
increase, decrease or remain the same?
• For purely inductive circuit
• From loop rule VL = Em
• So amplitude voltage, VL stays the same
• IL depends on XL which depends on ωd by
• So IL decreases
V
V
IL =
L
XL
=
L
ωd L
Related documents
Homework 22
Homework 22
I=VY V=IZ Circuit Element Admittance Y Impedance Z
I=VY V=IZ Circuit Element Admittance Y Impedance Z
Unit: Graphs of Trigonometric Functions
Unit: Graphs of Trigonometric Functions
Research interests My current research interests focus on three
Research interests My current research interests focus on three
How To Validate Canada SIN (Numbers)
How To Validate Canada SIN (Numbers)
Induction
Induction
Trigonometry PracticeTest C (Graphing and Identities) Name___________________________________
Trigonometry PracticeTest C (Graphing and Identities) Name___________________________________
experiment_V
experiment_V
Group 22: Ursuline Academy of Dallas
Group 22: Ursuline Academy of Dallas
Mechanics 105 chapter 12
Mechanics 105 chapter 12