Chapter 8 Natural and Step Responses of RLC Circuits
Transcript of Chapter 8 Natural and Step Responses of RLC Circuits
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Chapter 8 Natural and Step Responses of
RLC
Circuits
8.1-2 The Natural Response of a Parallel RLC Circuit
8.3 The Step Response of a Parallel RLC Circuit
8.4 The Natural and Step Response of a Series RLC Circuit
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Key points
What do the response curves of over-, under-, and critically-damped circuits look like? How to choose R, L, C values to achieve fast switching or to prevent overshooting damage?
What are the initial conditions in an RLC circuit? How to use them to determine the expansion coefficients of the complete solution?
Comparisons between: (1) natural & step responses, (2) parallel, series, or general RLC.
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Section 8.1, 8.2 The Natural Response of a Parallel RLC Circuit
1. ODE, ICs, general solution of parallel voltage
2. Over-damped response3. Under-damped response4. Critically-damped response
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The governing ordinary differential equation (ODE)
.0)(100
R
vtdtvL
IdtdvC
t
By KCL:
.012
2
LCv
dtdv
RCdtvd
Perform time derivative, we got a linear 2nd- order ODE of v(t)
with constant coefficients:
V0
, I0
, v(t)
must satisfy the passive sign convention.
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The two initial conditions (ICs)
The capacitor voltage cannot change abruptly,
)2()0()0( ,)0(
,)0()0()0( ,)0(
00
0
000
RCV
CIvv
dtdvCi
RVIiiiIi
Ct
CC
RLCL
)1()0( 0Vv
The inductor current cannot change abruptly,
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General solution
.012 LCRC
ss
Assume the solution is , where A, s are unknown constants to be solved.
Substitute into the ODE, we got an algebraic (characteristic) equation of s determined by the circuit parameters:
stAetv )(
where the expansion constants A1
, A2
will be determined by the two initial conditions.
,)( 2121
tsts eAeAtv
Since the ODE is linear, linear combination of solutions remains a solution to the equation. The general solution of v(t)
must be of the form:
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Neper and resonance frequencies
In general, s has two roots, which can be (1) distinct real, (2) degenerate real, or (3) complex conjugate pair.
,12
12
1 20
22
2,1
LCRCRCs
LC1
0
,2
1RC
where
…resonance (natural) frequency
…neper frequency
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Three types of natural response
Over-damped real, distinctroots s1
, s2
Under-damped complex roots
s1 = (s2
)*
Critically-damped real, equal roots
s1 = s2
The Circuit is When Solutions
How the circuit reaches its steady state depends on the relative magnitudes of and 0
:
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where are distinct real.
Over-damped response ( >0
)
The complete solution and its derivative are of the form:
.)(
,)(21
21
2211
21tsts
tsts
esAesAtv
eAeAtv
20
22,1 s
Substitute the two ICs:
)2()0(
)1()0(
002211
021
RCV
CIAsAsv
VAAv solve A1
, A2
.
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Example 8.2: Discharging a parallel RLC circuit (1)
12 V 30 mA
Q: v(t), iC (t), iL (t), iR (t)=?
kHz. 10)102)(105(
11
,kHz 5.12)102)(200(2
12
1
720
7
LC
RC
>0
, over- damped
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Example 8.2: Solving the parameters (2)
The 2 distinct real roots of s are:
.kHz 20
,kHz 520
22
20
21
s
s
…|s2
| >(fast)
…|s1
| <(slow)
45020512
21
2100
2211
021
AAAA
RCV
CIAsAs
VAA
The 2 expansion coefficients are:
V. 26,V 14 21 AA
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Example 8.2: The parallel voltage evolution (3)
Converge to zero
|s1
| <(slow) dominates
|s2
| >(fast) dominates
V. 2614)( 20000500021
21 tttsts eeeAeAtv
“Over” damp
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Example 8.2: The branch currents evolution (4)
The branch current through R is:
mA. 13070 200)()( 200005000 tt
R eetvti
The branch current through L is:
mA. 2656)(mH 051mA 30)( 200005000
0
ttt
L eetdtvti
The branch current through C is:
mA. 10414μF) 2.0()( 200005000 ttC ee
dtdvti
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Example 8.2: The branch currents evolution (5)
Converge to zero
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where is the damped frequency.
General solution to under-damped response ( <0
)
The two roots of s are complex conjugate pair:
220 d
,20
22,1 djs
.sincos
sincos
sincossincos
)(
21
2121
21
)(2
)(1
tBtBe
tAAjtAAe
tjtAtjtAe
eAeAtv
ddt
ddt
ddddt
tjtj dd
The general solution is reformulated as:
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Solving the expansion coefficients B1
, B2
by ICs
Substitute the two ICs:
)2()0(
)1()0(
0021
01
RCV
CIBBv
VBv
d solve B1
, B2
.
.sincos
cossin
sincos)(
1221
2
1
tBBtBBe
teteB
teteBtv
ddddt
dt
ddt
dt
ddt
The derivative of v(t)
is:
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Example 8.4: Discharging a parallel RLC circuit (1)
0 V-12.25 mA
Q: v(t), iC (t), iL (t), iR (t)=?
kHz. 1)1025.1)(8(
11
,kHz 2.0)1025.1)(102(2
12
1
70
74
LC
RC
<0
, under- damped
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Example 8.4: Solving the parameters (2)
.kHz 98.02.01 22220 d
The damped frequency is:
The 2 expansion coefficients are:
V 100,0
)2(
)1(0
2
100
21
01
BB
RCV
CIBB
VB
d
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Example 8.4: The parallel voltage evolution (3)
.V 980sin100sincos)( 20021 teteBteBtv t
dt
dt
The voltage oscillates (~d )
and
approaches the final value (~), different from the over- damped case (no oscillation, 2 decay constants).
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Example 8.4: The branch currents evolutions (4)
The three branch currents are:
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Rules for circuit designers
If one desires the circuit reaches the final value as fast as possible while the minor oscillation is of less concern, choosing R, L, C values to satisfy under-damped condition.
If one concerns that the response not exceed its final value to prevent potential damage, designing the system to be over-damped at the cost of slower response.
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General solution to critically-damped response (=0
)
Two identical real roots of s make
The general solution is reformulated as:
,)()( 02121stststst eAeAAeAeAtv
not possible to satisfy 2 independent ICs (V0
, I0
) with a single expansion constant A0
.
.)( 21 DtDetv t
You can prove the validity of this form by substituting it into the ODE:
.0)()()()()( 11 tvLCtvRCtv
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Solving the expansion coefficients D1
, D2
by ICs
Substitute the two ICs:
)2()0(
)1()0(
0021
02
RCV
CIDDv
VDv
solve D1
, D2
.
.)( 12121tttt etDDDeDteeDtv
The derivative of v(t)
is:
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Example 8.5: Discharging a parallel RLC circuit (1)
0 V-12.25 mA
R
Q: What is R such that the circuit is critically- damped? Plot the corresponding v(t).
.k 41025.1
821
21 ,1
21 , 70
C
LRLCRC
Increasing R tends to bring the circuit from over- to critically- and even under-damped.
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Example 8.5: Solving the parameters (2)
The neper frequency is:
The 2 expansion coefficients are:
ms. 11
,kHz 1)1025.1)(104(2
12
173
RC
0skV 98
)2(
)1(0
2
100
21
02
DD
RCV
CIDD
VD
-12.25 mA
0.125 F
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Example 8.5: The parallel voltage evolution (3)
98 V/ms
.V 000,98)( 100021
ttt teeDteDtv
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Procedures of solving nature response of parallel RLC
Calculate parameters and .
Write the form of v(t)
by comparing and
:
Find the expansion constants (A1
, A2
), (B1
, B2
), or (D1
, D2
)
by two ICs:
LC10 1)2( RC
)2()0(
),1()0(
00
0
RCV
CIv
Vv
. if ,
, if , ,sincos
, if ,- ,
)(
021
022
021
020
22,121
21
DtDe
tBtBe
seAeA
tvt
dddt
tsts
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Section 8.3 The Step Response of a Parallel RLC Circuit
1. Inhomogeneous ODE, ICs, and general solution
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The homogeneous ODE
.)(100 s
tI
Rvtdtv
LI
dtdvC
By KCL:
.012
2
LCv
dtdv
RCdtvd
Perform time derivative, we got a homogeneous ODE of v(t)
independent of the source current Is :
V0 I0Is
+
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The inhomogeneous ODE
LCI
LCi
dtdi
RCdtid
dtdiLv
IRvi
dtdvC
sLLL
L
sL
1
,
,2
2
Change the unknown to the inductor current iL (t):
iLV0 I0
Is
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The two initial conditions (ICs)
The inductor current cannot change abruptly,
)2()0(,)0(
),0()0(
0
0
0
L
VidtdiLv
vVv
Lt
LL
LC
)1()0( 0IiL
The capacitor voltage cannot change abruptly,
IsiL
V0 I0
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General solution
where the three types of nature responses were elucidated in Section 8.2:
The solution is the sum of final current If = Is and the nature response iL,nature (t):
),()( , tiIti natureLfL
. if ,
, if ,sincos
, if ,
)(
021
021
02121
DtDeI
tBtBeI
eAeAI
tit
f
ddt
f
tstsf
L
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Example 8.7: Charging a parallel RLC circuit (1)
625
Is = 24 mA V0 = 0
I0
= 0
Q: iL (t) = ?
kHz. 40)105.2)(105.2(
11
,kHz 32)105.2)(625(2
12
1
820
8
LC
RC
<0
, under- damped
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Example 8.7: Solving the parameters (2)
.kHz 243240 22220 d
The complete solution is of the form:
The 2 expansion coefficients are:
mA 32,mA 24
)2(0
)1(0
2
10
21
01
BB
LVBB
IBI
d
s
,sincos)( 21 tBtBeIti ddt
sL
where
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Example 8.7: Inductor current evolution (3)
.mA )000,24sin(32)000,24cos(2424)( 000,32000,32 teteti ttL
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Example 8.9: Charging of parallel RLC circuits (1)
Q: Compare iL (t)
when the resistance R = 625 (under-damp), 500
(critical damp), 400
(over-damp), respectively.
Is = 24 mA
Initial & final conditions remain: iL (0+)=0, i'L (0+)=0, If =24 mA. Different R’s give different functional forms and expansion constants.
V0 = 0
I0
= 0
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Example 8.9: Comparison of rise times (2)
The current of an under-damped circuit rises faster than that of its over-damped counterpart.
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Section 8.4 The Natural and Step Response of a Series RLC Circuit1. Modifications of time constant, neper
frequency
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ODE of nature response
.0)(100
ttdti
CV
dtdiLRi
.02
2
LCi
dtdi
LR
dtid
RC1
in parallel RLC
By KVL:
By derivative:
V0
, I0
, i(t)
must satisfy the passive sign convention.
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The two initial conditions (ICs)
The inductor cannot change abruptly,
)2()0()0( ,)0(
,)0()0()0( ,)0(
00
0
000
L
RIViidtdiLv
RIVvvvVv
Lt
LL
RCLC
)1()0( 0Ii
The capacitor voltage cannot change abruptly,
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General solution
.012 LC
sLRs
Substitute into the ODE, we got a different characteristic equation of s:
stAeti )(
021
021
021
if ,
if ,sincos
if ,
)(
21
DtDe
tBtBe
eAeA
tit
ddt
tsts
The form of s1,2
determines the form of general solution:
.20
22,1 s
. ,1 ,2
2200 dLCL
Rwhere1)2( RC in parallel RLC
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Example 8.11: Discharging a series RLC circuit (1)
vC (0-)
= 100 V, V0
= -100 V
I0 = 0
kHz. 10
)101)(1.0(11
,kHz 8.2)1.0(2
5602
70 LC
LR
<0
, under- damped
Q: i(t), vC (t) =?
+
100 V
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Example 8.11: Solving the parameters (2)
.kHz 6.98.210 22220 d
The damped frequency is:
The 2 expansion coefficients are:
mA 2.104,0
)2(
)1(0
2
100
21
01
BB
LRIVBB
IB
d
9.6 kHz 100 mH
-100 V
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Example 8.11: Loop current evolution (3)
.mA 600,9sin2.104sincos)( 800,221 tetBtBeti t
ddt
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Example 8.11: Capacitor voltage evolution (4)
.V 600,9sin17.29600,9cos100
)()()(800,2 tte
tiLtRitvt
c
When the capacitor energy starts to decrease, the inductor energy starts to increase.
Inductor energy starts to decrease before capacitor energy decays to 0.
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ODEs of step response
By KVL:
The homogeneous and inhomogeneous ODEs of i(t)
and vC (t)
are:
V0
I0
Vs+
.)(100 s
tVtdti
CV
dtdiLRi
. and ,0 2
2
2
2
LCV
LCv
dtdv
LR
dtvd
LCi
dtdi
LR
dtid sCCC
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The two initial conditions (ICs)
The capacitor voltage cannot change abruptly,
)2()0(,)0(
),0()0(
0
0
0
CIv
dtdvCi
iIi
Ct
CC
CL
)1()0( 0VvC
The inductor current cannot change abruptly,
V0
I0
Vs+
vC (t)
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General solution
where the three types of nature responses were elucidated in Section 8.4.
The solution is the sum of final voltage Vf =Vs
and the nature response vC,nature (t):
),()( , tvVtv natureCfC
. if ,
, if ,sincos
, if ,
)(
021
021
02121
DtDeV
tBtBeV
eAeAV
tvt
f
ddt
f
tstsf
C
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Key points
What do the response curves of over-, under-, and critically-damped circuits look like? How to choose R, L, C values to achieve fast switching or to prevent overshooting damage?
What are the initial conditions in an RLC circuit? How to use them to determine the expansion coefficients of the complete solution?
Comparisons between: (1) natural & step responses, (2) parallel, series, or general RLC.