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11C.T. PanC.T. Pan 11
CAPACITANCE, CAPACITANCE, INDUCTANCE, INDUCTANCE, AND AND MUTUAL INDUCTANCE MUTUAL INDUCTANCE
22C.T. PanC.T. Pan
6.1 The Capacitor6.1 The Capacitor
6.2 The Inductor6.2 The Inductor
6.3 Series6.3 Series--Parallel Combinations of Capacitance Parallel Combinations of Capacitance and Inductanceand Inductance
6.4 Mutual Inductance6.4 Mutual Inductance
22
In this chapter, two new and important passive In this chapter, two new and important passive linear components are introduced.linear components are introduced.
They are ideal models.They are ideal models.
Resistors dissipate energy but capacitors and Resistors dissipate energy but capacitors and inductors are energy storage components.inductors are energy storage components.
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6.1 The Capacitor6.1 The Capacitor
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6.1 The Capacitor6.1 The CapacitorCircuit symbol and component model.Circuit symbol and component model.
, ( ) t
C Cq C v q(t)= i d
q : chargeC : capacitance , in F(Farad)
τ τ⋅ ∫@
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6.1 The Capacitor6.1 The Capacitor0
0
00
1 1 1( ) ( ) ( ) ( )
1( ) ( ) ( ) .......... (A)
( ) ..................... (B)
1 farad = 1 Coulomb/Volt
t t
C C C Ct
t
C C Ct
CC
v t i d i d i dC C C
v t v t i dC
dvdqi t Cdt dt
τ τ τ τ τ τ
τ τ
−∞= = +
+
= =
∫ ∫ ∫
∫@
The unit of capacitance is chosen to be farad in honor of The unit of capacitance is chosen to be farad in honor of the English physicist , Michael Faraday(1791the English physicist , Michael Faraday(1791--1867). 1867).
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6.1 The Capacitor6.1 The CapacitorExample 1 : A parallelExample 1 : A parallel--plate capacitorplate capacitor
ε
C=
: the permittivity of the dielectric material between the plates
Ad
ε
ε
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6.1 The Capacitor6.1 The Capacitor
ε( )
( )2
2
( ) ( ) ( )
1( ) 02 2
c c c c
c c
cC C C
t
c
If v > 0 and i > 0 , or v < 0 and i < 0 the capacitor is being charged.If v i < 0 , the capacitor is discharging.
dv tp(t)= v t i t v t C
dtEnergy in a capacitor
qw p d C v tC
τ τ−∞
⋅
=
= = = ≥∫
Example 1 : (cont.)Example 1 : (cont.)
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6.1 The Capacitor6.1 The Capacitor
0
( ) ( )
1( ) ( ) ( )
lim ( ) ( ) , (0 ) (0 )
C
t
C C Ct
C C C C
C
b v t is a continuous function if there is only finite strength energy sources inside the circuit.
v t v t i dC
v t v t v v
i.e. v (t
ε
ε
ε τ τ
ε
+
+ −
→
+ = +
+ = =
∫Q
C) can not change abruptly for finite i (t)
( ) . ,
C ca When v is constant , then i = 0.ie equivalent to open circuit
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6.1 The Capacitor6.1 The Capacitor
(c) An ideal capacitor does not dissipate energy . It storesenergy in the electrical field .
(d) A nonideal capacitor has a leakage resistance
ESR : equivalent series resistance
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6.2 The Inductor6.2 The Inductor
iL0
λ
( ) ( ) , tt
L LL i v d
λ : flux linkage , in web - turnsL : inductance , in H (Henry)
λ λ τ τ⋅ = ∫@
Circuit symbol and component model.Circuit symbol and component model.
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( ) ( ) ( )
( ) ( ) ( )
( ) ( )
( ) ( ) ( )
( ) ( ) ( )
0
0
00
2
1 1 1
1 ( )
( )
Energy in an inductor 1 0 2
t t t
L L L Lt
t
L L Lt
LL
LL L L
t
L
i v d v d v dL L L
i t i t v d ALdi tdv t L B
dt dtdi t
p t v i Li tdt
w t p d Li t
τ τ τ τ τ τ
τ τ
λ
τ τ
−∞ −∞= = +
= + − − − − − − − − − −
= = − − − − − − − − − − − − −
= =
= = ≥
∫ ∫ ∫
∫
∫
6.2 The Inductor6.2 The Inductor
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il
NA
H : magnetic field intensityH : magnetic field intensityB : flux density B : flux density
,
, perm eability of the core
H d l N i
N iH l N i Hl
N iB Hl
µµ µ
=
= =
= =
∫ruuv
—
Example 2 : An InductorExample 2 : An Inductor6.2 The Inductor6.2 The Inductor
: f lu xB d Aφ ∫ur ur
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il
NA
Example 2 : (cont.)Example 2 : (cont.)6.2 The Inductor6.2 The Inductor
2
2
, f lu x l i n k a g e
A N iB AlA N iN
lA NL
i l
µφ
µλ φ
λ µ
= =
= =
∴ = =
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6.2 The Inductor6.2 The InductorThe unit of inductance is the henry (H) , named in honor The unit of inductance is the henry (H) , named in honor of the American inventor Joseph Henry (1797of the American inventor Joseph Henry (1797--1878) .1878) .
1H = 1 volt1H = 1 volt--second / amperesecond / ampere(a) when (a) when iiL L is constant , then is constant , then vvLL=0 .=0 .
i.e.i.e. , equivalent to short circuit, equivalent to short circuit(b) (b) iiLL(t) is a continuous function if there is only finite (t) is a continuous function if there is only finite
strength source inside the circuit .strength source inside the circuit .
( ) ( ) ( )
( ) ( ) ( ) ( )( ) ( )
0
1
lim , 0 0
. . can not change abruptly for finite .
t
L L Lt
L L L L
L L
i t i t v dtL
i t i t or i i
i e i t v t
τ+∈
+ −
∈→
+ ∈ = +
+ ∈ = =
∫
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6.2 The Inductor6.2 The Inductor(c) An ideal inductor does not dissipate energy .(c) An ideal inductor does not dissipate energy .
It stores energy in the magnetic field .It stores energy in the magnetic field .
(d) A nonideal inductor contains winding resistance and (d) A nonideal inductor contains winding resistance and parasitic capacitance .parasitic capacitance .
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6.2 The Inductor6.2 The InductorExample 3 : Under dc and steady state conditions, Example 3 : Under dc and steady state conditions,
find (a) I , Vfind (a) I , VCC & I& ILL , (b) W, (b) WCC and Wand WLL
2
2
12 21 5
5 101 1 10 5021 2 2 42
L
C L
C
L
I I A
V I V
W J
W J
= = =+
= =
= × × =
= × × =
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6.2 The Inductor6.2 The Inductor(a)(a) The capacity of C and L to store energy makes themThe capacity of C and L to store energy makes them
useful as temporary voltage or current sources , i.e. , useful as temporary voltage or current sources , i.e. , they can be used for generating a large amount ofthey can be used for generating a large amount ofvoltage or current for a short period of time.voltage or current for a short period of time.
(b)(b) The continuity property of VThe continuity property of VCC(t) and i(t) and iLL(t) makes (t) makes inductors useful for spark or arc suppression andinductors useful for spark or arc suppression andfor converting pulsating voltage into relativelyfor converting pulsating voltage into relativelysmooth dc voltage.smooth dc voltage.
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6.2 The Inductor6.2 The Inductor
(c)(c) The frequency sensitive property of L and C makesThe frequency sensitive property of L and C makesthem useful for frequency discrimination.them useful for frequency discrimination.
(eg. LP , HP , (eg. LP , HP , BP filters)BP filters)
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6.3 Series6.3 Series--Parallel Combinations ofParallel Combinations ofCapacitance and InductanceCapacitance and Inductance
N capacitors in parallelN capacitors in parallel
ii1 i2 iN
v c1 c2 cNL1 2
1 2
1
1 2
(0) (0)
N
N
N
k eqk
eq N
k
i i i idv dv dvc c cdt dt dt
dv dvc Cdt dt
C c c cv v
=
= + + +
= + + +
= =
∴ = + + +
=
∑
Q L
L
L1 2
1 2
(0) (0) (0)= =
N
N
v v vv v v v
= = == =
LL
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6.3 Series6.3 Series--Parallel Combinations ofParallel Combinations ofCapacitance and InductanceCapacitance and Inductance
N capacitors in seriesN capacitors in series
LL
( ) ( ) ( )
( )
( ) ( )
( ) ( ) ( ) ( )
0
0
0
0
1 1
0
1 2
0 1 0 2 0 0
1
1 ( )
1
1 1 1 1
t
k kk t
tN N
k ok kk t
t
eq t
eq N
N
v t i d v tc
v i d v tc
i d v tC
C C C C
v t v t v t v t
τ τ
τ τ
τ τ
= =
= +
∴ = +
= +
∴ = + + +
= + + +
∫
∑ ∑∫
∫
Q
L
L
1 2 Ni i i= = =L
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6.3 Series6.3 Series--Parallel Combinations ofParallel Combinations ofCapacitance and InductanceCapacitance and Inductance
N inductors in seriesN inductors in series
L1 2
1 2
1
1 2
1 2
(0) (0) (0) (0)
N
N
N
k eqk
eq N
N
v v v vdi di diL L Ldt dt dt
di diL Ldt dt
L L L Li i i i
=
= + + +
= + + +
= =
∴ = + + +
= = =
∑
Q L
L
LL
1 2
1 2
(0) (0) (0)( ) (t)= = ( ) ( )
N
N
i i ii t i i t i t
= = == =
LL
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6.3 Series6.3 Series--Parallel Combinations ofParallel Combinations ofCapacitance and InductanceCapacitance and Inductance
N inductors in parallelN inductors in parallel
L
( ) ( ) ( )
( )
( )
( ) ( ) ( ) ( )
0 0 0
0
0
1 0 2 0 01 2
01 1
0
1 2
0 1 0 2 0 0
1 1 1
1
1
1 1 1 1
t t t
Nt t tN
N Nt
ktk kk
t
teq
eq N
N
i i t vd i t vd i t vdL L L
vd i tL
vd i tL
L L L L
i t i t i t i t
τ τ τ
τ
τ
= =
= + + + + + +
= +
= +
∴ = + + +
= + + +
∫ ∫ ∫
∑ ∑∫
∫
L
L
L
1 2
1 2
N
N
v v v vi i i i
= = = =∴ = + + +Q L
L
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6.3 Series6.3 Series--Parallel Combinations ofParallel Combinations ofCapacitance and InductanceCapacitance and Inductance
Resistor Capacitor Inductor
V-I
I-V
P or W
series
parallel
dc case open circuit1 2eqC C C= +
1 2
1 2eq
C CCC C
=+
21 2
W Cv=
dvi Cdt
=
00
1( ) t
tv v t i dt
C= + ∫ V RI=
1 I VR
=
22VP I R
R= =
1 2eqR R R= +
1 2
1 2eq
R RRR R
=+
same
21 2
W Li=
1 2eqL L L= +
1 2
1 2eq
L LLL L
=+
short circuit
00
1( ) v t
ti i t d
Lτ= + ∫
div Ldt
=
In summaryIn summary
6.4 Mutual Inductance6.4 Mutual Inductance
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Circuit symbol and model of coupling inductorsCircuit symbol and model of coupling inductors
1i 2i
1v+
−2v
+
−1L 2L
12M LL11 , L, L22 : self inductances: self inductancesM : mutual inductanceM : mutual inductanceunit : in H unit : in H
2
1 211
1 22
di div L Mdt dtdi div M Ldt dt
= +
= +
6.4 Mutual Inductance6.4 Mutual Inductance
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Example 4 : Example 4 : Mutual inductanceMutual inductance
1 2
1 1
Apply I , with i =0
H dl=N I⋅⋅∫ur v
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Assume uniform magnetic field intensity HAssume uniform magnetic field intensity H1 1 1 1
1 1
21 1 1 2 1
1 1 2 2
21 1 2 1 2
1 2 11 1
,
;
,
N I N IH B Hl l
A N IB d Al
A N I A N N IN Nl l
A N A N NL MI l I l
µµ
µφ
µ µλ φ λ φ
λ µ λ µ
= ∴ = =
= ⋅ =
= = = =
= =
∫
@ @
6.4 Mutual Inductance6.4 Mutual Inductance
6.4 Mutual Inductance6.4 Mutual Inductance
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Dot convention for mutually coupled inductors: Dot convention for mutually coupled inductors: When the reference direction for a current enters the When the reference direction for a current enters the dotted terminal of a coil , the polarity of the induced dotted terminal of a coil , the polarity of the induced voltage in the other coil is positive at its correspondingvoltage in the other coil is positive at its correspondingdotted terminal.dotted terminal.
6.4 Mutual Inductance6.4 Mutual Inductance
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ii11↗↗ , , vv11>0 , >0 , φ↗φ↗ , ( i, ( i22=0 )=0 )
Another dot of coil 2 should be placed in terminal c.Another dot of coil 2 should be placed in terminal c.
V1>0 V2
6.4 Mutual Inductance6.4 Mutual Inductance
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Conceptually , one can connect a resistor at cd terminals. Then i2 will be negative.The generated flux of i2 will oppose the increasing of φdue to increasing i1 ( Lentz law ).Hence , another dot should be placed at c terminal.
V1>0 V2
6.4 Mutual Inductance6.4 Mutual Inductance
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In case , the other dot is placed at d terminal , then i2will be positive.Hence , the generated flux of i2 will be added to the increasing φ due to i1.
V1>0 V2
6.4 Mutual Inductance6.4 Mutual Inductance
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Then the induced voltage at coil two will increase Then the induced voltage at coil two will increase and so will iand so will i22..This will violate the conservation of energy. This will violate the conservation of energy.
V1>0 V2
6.4 Mutual Inductance6.4 Mutual Inductance
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The procedure for determining dot markingsThe procedure for determining dot markings
Step1Step1 Assign current direction references for the coils.Assign current direction references for the coils.
Step2Step2 Arbitrarily select one terminal of one coil and Arbitrarily select one terminal of one coil and mark it with a dot.mark it with a dot.
Step3Step3 Use the rightUse the right--hand rule to determine the direction hand rule to determine the direction of the magnetic flux due to the current of the otheof the magnetic flux due to the current of the other r coil.coil.
6.4 Mutual Inductance6.4 Mutual Inductance
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Step4Step4 If this flux direction has the same direction as that If this flux direction has the same direction as that of the first dot terminal current , then the secondof the first dot terminal current , then the seconddot is placed at the terminal where the second dot is placed at the terminal where the second current enters. Otherwise, the second dot should current enters. Otherwise, the second dot should be placed at the terminal where the second currentbe placed at the terminal where the second currentleaves.leaves.
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6.4 Mutual Inductance6.4 Mutual InductanceExample 5 : Determining dot markingsExample 5 : Determining dot markings
Step 1Step 1 : Assign : Assign ii11 , , ii22 , , ii33 directions.directions.
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6.4 Mutual Inductance6.4 Mutual InductanceExample 5 : (cont.)Example 5 : (cont.)
Step 2Step 2 : :
For coils 1 and 2, choose For coils 1 and 2, choose first dot as followsfirst dot as follows
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6.4 Mutual Inductance6.4 Mutual InductanceExample 5 : (cont.)Example 5 : (cont.)
For coils 1 and 3For coils 1 and 3
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6.4 Mutual Inductance6.4 Mutual InductanceExample 5 : (cont.)Example 5 : (cont.)
For coils 2 and 3For coils 2 and 3
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6.4 Mutual Inductance6.4 Mutual InductanceExample 5 : (cont.)Example 5 : (cont.)Step 3Step 3 : :
Check the relative flux directions and determine the Check the relative flux directions and determine the dot position at the other coildot position at the other coil
For coil 1 and 2For coil 1 and 2and are in the same directionand are in the same direction
1L 2L
12M
1φ 2φ
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6.4 Mutual Inductance6.4 Mutual InductanceExample 5 : (cont.)Example 5 : (cont.)
For coil 1 and 3For coil 1 and 3
and are in opposite directionand are in opposite direction
1L 3L
1φ 3φ
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6.4 Mutual Inductance6.4 Mutual InductanceExample 5 : (cont.)Example 5 : (cont.)
For coil 2 and 3For coil 2 and 3
and are in opposite directionand are in opposite direction2φ 3φ
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6.4 Mutual Inductance6.4 Mutual InductanceExample 5 : (cont.)Example 5 : (cont.)
In summaryIn summary+
_
+
_
i1 i2
v1 v2L1 L2
M12
i3+
_v3L3
M13M23
31 21 1 12 13
31 22 12 2 23
31 23 13 23 3
didi div L M Mdt dt dt
didi div M L Mdt dt dt
didi div M M Ldt dt dt
= + −
= + −
= − − +
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6.4 Mutual Inductance6.4 Mutual Inductance
If the physical arrangement of the coils are not known, If the physical arrangement of the coils are not known, the relative polarities of the magnetically coupled coils the relative polarities of the magnetically coupled coils can be determined experimentally. We needcan be determined experimentally. We need
a dc voltage source a dc voltage source VVSSa resistor a resistor RR : to limit the current: to limit the currenta switch a switch SSa dc voltmetera dc voltmeter
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6.4 Mutual Inductance6.4 Mutual Inductance
Step 1Step 1 : Assign current directions and arbitrarily assign : Assign current directions and arbitrarily assign one dot at coil one.one dot at coil one.
1L 2L
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6.4 Mutual Inductance6.4 Mutual Inductance
Step 2Step 2 : Connect the setup as follows.: Connect the setup as follows.
1L 2L
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6.4 Mutual Inductance6.4 Mutual InductanceStep 3Step 3 : Determine the voltmeter deflection when the : Determine the voltmeter deflection when the
switch is closed.switch is closed.If the momentary deflection is upscale, If the momentary deflection is upscale, thenthen
1L 2L
If the momentary deflection is downscale, If the momentary deflection is downscale, thenthen
1L 2L
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The reciprocal property of the mutual inductance can beThe reciprocal property of the mutual inductance can beproved by considering the energy relationship .proved by considering the energy relationship .Step 1Step 1 : i: i22=0 , i=0 , i11 increased from zero to I .increased from zero to I .
1
11 1
12 21
1 1 1 2 2
11 1
1 10
211 1 1 10
( )
2
t
I
div Ldt
div Mdt
input power p v i v idiL idt
input energy w p d
LL i di I
τ
=
=
= +
=
=
= =
∫
∫
1i 2i
1v+
−2v
+
−1L 2L
12M
6.4 Mutual Inductance6.4 Mutual Inductance
Step2 Step2 : keep i: keep i11=I , i=I , i22 is increased from zero to Iis increased from zero to I222 2
1 1 12 12
2 22 21 2 2
di didIv L M Mdt dt dt
di didIv M L Ldt dt dt
= + =
= + =
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2 1 1 2 2
2 212 1 2 2 ( )
p v I v idi diM I L idt dt
= +
= +
2 2
2 2
12 1 2 2 2 20 0
212 1 2 2 2
1 2
I I
w p d
M I di L i di
M I I L I
τ=
= +
= +
∫∫ ∫
Input powerInput power
6.4 Mutual Inductance6.4 Mutual Inductance
Input energyInput energy
2 21 2 1 1 2 2 1 2 12
1 12 2
w w w L I L I I I M= + = + +
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Total energy when iTotal energy when i11=I=I11 , i, i22=I=I22
Similarly , if we reverse the procedure , by first Similarly , if we reverse the procedure , by first increasing iincreasing i2 2 from zero to Ifrom zero to I22 and then increasing iand then increasing i11 from from zero to Izero to I11, the total energy is, the total energy is
2 21 2 1 1 2 2 1 2 21
1 12 2
w w w L I L I I I M= + = + +
Hence , MHence , M1212=M=M2121=M=M
6.4 Mutual Inductance6.4 Mutual Inductance
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1 2
0 110 , 2
1 1 , 2
1 ,
MkL L
k
k loosely coupling
k closely coupling
k unity coupling
≤ ≤
< <
≤ <
=
@
6.4 Mutual Inductance6.4 Mutual Inductance
Definition of coefficient of coupling kDefinition of coefficient of coupling k
2 21 1 2 2 1 2
1 1 02 2
w L i L i Mi i= + ± ≥
2 21 1 2 2 1 2
1 1 02 2
L i L i Mi i+ − =
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According to dot convention chosen , the total energy According to dot convention chosen , the total energy stored in the coupled inductors should be stored in the coupled inductors should be
In particular , consider the limiting caseIn particular , consider the limiting case
21 21 2 1 2 1 2( ) ( ) 02 2
L Li i i i L L M− + − =
6.4 Mutual Inductance6.4 Mutual Inductance
The above equation can be put into the following form The above equation can be put into the following form
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Thus , Thus , ww(t) (t) ≧≧0 only if0 only if
1 2L L M≥
when iwhen i11 and iand i22 are either both positive or both negative are either both positive or both negative Hence , kHence , k≦≦11
6.4 Mutual Inductance6.4 Mutual Inductance
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5Ω 20Ω
gigi
16Hi
2i 60Ω
1i
4Hi
Example 6 : Finding meshExample 6 : Finding mesh--current equations for a circuit current equations for a circuit with magnetically coupled coils.with magnetically coupled coils.
Three meshes and one Three meshes and one current source , only need current source , only need two unknowns , say itwo unknowns , say i11 and and ii22
6.4 Mutual Inductance6.4 Mutual Inductance
Note : current iNote : current i4H 4H = i= i11(t)(t)current icurrent i16H 16H = i= ig g -- ii22
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Due to existence of mutual inductance M=8H , thereDue to existence of mutual inductance M=8H , thereare two voltage terms for each coil . are two voltage terms for each coil .
6.4 Mutual Inductance6.4 Mutual Inductance
One can use dependence source to eliminate the One can use dependence source to eliminate the coupling relation as follows.coupling relation as follows.
5Ω 20Ω
gigi 2
i 60Ω
1i
168 Hd idt
18 didt
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6.4 Mutual Inductance6.4 Mutual Inductance
1
12 1 2 1
2
2 1 2 2 1
,
4 8 ( ) 20( ) 5( ) 0
20( ) 60 16 ( ) 8 0
g g
g
Hence for i meshdi d i i i i i idt dt
For i meshd di i i i i idt dt
+ − + − + − =
− + + − − =
4H
5Ω 20Ω
gigi
16H2i
60Ω
1i+-
+-
168 Hd idt
18 didt
n Objective 1 : Know and be able to use the componentmodel of an inductor
n Objective 2 : Know and be able to use the componentmodel of a capacitor.
n Objective 3 : Be able to find the equivalent inductor (capacitor) together with it equivalent initial condition for inductors (capacitors) connected in series and in parallel.
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SummarySummary
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SummarySummary
Chapter Problems : 6.46.196.216.266.406.41
Due within one week.
nObjective 4 : Understand the component model of coupling inductors and the dot convention as well as be able to write the mesh equations for a circuit containing coupling inductors.
Recommended