EE2003 Circuit Theory
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Transcript EE2003 Circuit Theory
Circuit Theory
Chapter 8
Second-Order Circuits
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1
Second-Order Circuits
Chapter 8
8.1
8.2
8.3
8.4
8.5
Examples of 2nd order RCL circuit
The source-free series RLC circuit
The source-free parallel RLC circuit
Step response of a series RLC circuit
Step response of a parallel RLC
2
8.1 Examples of Second
Order RLC circuits (1)
What is a 2nd order circuit?
A second-order circuit is characterized by a secondorder differential equation. It consists of resistors
and the equivalent of two energy storage elements.
RLC Series
RLC Parallel
RL T-config
RC Pi-config
3
8.2 Source-Free Series
RLC Circuits (1)
• The solution of the source-free
series RLC circuit is called as the
natural response of the circuit.
• The circuit is excited by the energy
initially stored in the capacitor and
inductor.
The 2nd
order of
expression
d 2 i R di i
0
2
L dt LC
dt
How to derive and how to solve?
4
8.2 Source-Free Series
RLC Circuits (2)
Method will be
illustrated
during the lecture
5
8.2 Source-Free Series
RLC Circuits (3)
There are three possible solutions for the following
2nd order differential equation:
d 2 i R di i
0
2
L dt LC
dt
=>
d 2i
di
2
2
a
w
0i 0
2
dt
dt
where
a
R
2L
and w0
1
LC
General 2nd order Form
The types of solutions for i(t) depend
on the relative values of a and w.
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8.2 Source-Free Series
RLC Circuits (4)
There are three possible solutions for the following
2nd order differential equation:
d 2i
di
2
2
a
w
i 0
0
2
dt
dt
1. If a > wo, over-damped case
i(t ) A1es1t A2es2t
2
where s1, 2 a a w0
2
2. If a = wo, critical damped case
i(t ) ( A2 A1t )eat
where
s1, 2 a
3. If a < wo, under-damped case
i(t ) e at ( B1 coswd t B2 sin wd t )
2
2
where w d w 0 a
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8.2 Source-Free Series
RLC Circuits (5)
Example 1
If R = 10 Ω, L = 5 H, and
C = 2 mF in 8.8, find α,
ω0, s1 and s2.
What type of natural
response will the circuit
have?
•
Please refer to lecture or textbook for more detail elaboration.
Answer: underdamped
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8.2 Source-Free Series
RLC Circuits (6)
Example 2
The circuit shown below
has reached steady state
at t = 0-.
If the make-before-break
switch moves to position b
at t = 0, calculate i(t) for
t > 0.
• Please refer to lecture or textbook for more detail elaboration.
Answer: i(t) = e–2.5t[5cos1.6583t – 7.538sin1.6583t] A
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8.3 Source-Free Parallel
RLC Circuits (1)
0
Let
1
i(0) I 0 v(t )dt
L
v(0) = V0
Apply KCL to the top node:
t
v 1
dv
vdt C 0
R L
dt
Taking the derivative with
respect to t and dividing by C
The 2nd
order of
expression
d 2 v 1 dv 1
v0
2
RC dt LC
dt
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8.3 Source-Free Parallel
RLC Circuits (2)
There are three possible solutions for the following
2nd order differential equation:
d 2v
dv
2a
w02v 0
2
dt
dt
where a
1
and w0
2RC
1
LC
1. If a > wo, over-damped case
v(t ) A1 es1t A2 es2t where s1,2 a
a 2 w0 2
2. If a = wo, critical damped case
v(t ) ( A2 A1t ) eat
where
s1, 2 a
3. If a < wo, under-damped case
v(t ) eat ( B1 coswd t B2 sin wd t )
where
wd
w 02 a 2
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8.3 Source-Free Parallel
RLC Circuits (3)
Example 3
Refer to the circuit shown below.
Find v(t) for t > 0.
• Please refer to lecture or textbook for more detail elaboration.
Answer:
v(t) = 66.67(e–10t – e–2.5t) V
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8.4 Step-Response Series
RLC Circuits (1)
• The step response
is obtained by the
sudden application
of a dc source.
The 2nd
order of
expression
vs
d 2 v R dv v
2
L dt LC LC
dt
The above equation has the same form as the equation for
source-free series RLC circuit.
• The same coefficients (important in determining the
frequency parameters).
• Different circuit variable in the equation.
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8.4 Step-Response Series
RLC Circuits (2)
The solution of the equation should have two components:
the transient response vt(t) & the steady-state response vss(t):
v(t ) vt (t ) vss (t )
The transient response vt is the same as that for source-free case
vt (t ) A1es1t A2es2t
(over-damped)
vt (t ) ( A1 A2t )eat
(critically damped)
vt (t ) eat ( A1 coswd t A2 sin wd t ) (under-damped)
The steady-state response is the final value of v(t).
vss(t) = v(∞)
The values of A1 and A2 are obtained from the initial conditions:
v(0) and dv(0)/dt.
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8.4 Step-Response Series
RLC Circuits (3)
Example 4
Having been in position for a long time, the
switch in the circuit below is moved to position b
at t = 0. Find v(t) and vR(t) for t > 0.
•
Please refer to lecture or textbook for more detail elaboration.
Answer: v(t) = {10 + [(–2cos3.464t – 1.1547sin3.464t)e–2t]} V
vR(t)= [2.31sin3.464t]e–2t V
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8.5 Step-Response Parallel
RLC Circuits (1)
• The step response
is obtained by the
sudden application
of a dc source.
The 2nd
order of
expression
d 2i 1 di i
Is
2
dt RC dt LC LC
It has the same form as the equation for source-free parallel
RLC circuit.
• The same coefficients (important in determining the
frequency parameters).
• Different circuit variable in the equation.
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8.5 Step-Response Parallel
RLC Circuits (2)
The solution of the equation should have two components:
the transient response vt(t) & the steady-state response vss(t):
i(t ) it (t ) iss (t )
The transient response it is the same as that for source-free case
it (t ) A1es1t A2es2t
(over-damped)
it (t ) ( A1 A2t )eat
(critical damped)
it (t ) eat ( A1 coswd t A2 sin wd t )
(under-damped)
The steady-state response is the final value of i(t).
iss(t) = i(∞) = Is
The values of A1 and A2 are obtained from the initial conditions:
i(0) and di(0)/dt.
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8.5 Step-Response Parallel
RLC Circuits (3)
Example 5
Find i(t) and v(t) for t > 0 in the circuit shown in
circuit shown below:
• Please refer to lecture or textbook for more detail elaboration.
Answer:
v(t) = Ldi/dt = 5x20sint = 100sint V
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