ExamplesonImpulseandStepResponseofSeries
RLC
Circuits
12.25
example: 12.8-3
Develop the differential equation governing
v
C
(
t) in
the circuit in Fig. 12.8-1and find its step response
for
L
=
16 mH,
C
=
10
m
F and
R
=
100
W
. Obtain
the rise time, peak time, settling time and maximum
percentage overshoot for this response.
Solution
Applying KCL at the junction between
R,
L and
C
along with the element equation of a capacitor yields
i t
C
dv t
dt
v t
R
C
C
( )
( )
( )
.
=
+
Applying KVL in the first mesh yields
L
di t
dt
v t
u t
C
( )
( )
( )
+
=
.
Substituting the first equation
in the second one results in
LC
d v t
dt
L
R
dv t
dt
v t
u t
i e
d v t
dt
RC
dv t
C
C
C
C
C
2
2
2
2
1
( )
( )
( )
( )
. .,
( )
(
+
+
=
+
))
( )
( )
dt
LC
v t
LC
u t
C
+
=
1
1
The critical resistance of this circuiit is
1
2
L
C
.
Substituting the parameter values,
d v t
dt
dv t
dt
v t
t
C
C
C
n
2
2
3
2
2
10
2500
2500
0
2500
( )
( )
( )
+
+
=
≥
=
+
for
rad/s
w
,,
rad/s
2
10
0 2
1
2449 5
3
2
xw
x
w
x w
n
d
n
=
⇒ =
∴
=
−
=
.
.
The final value of step response is obtained by replacing the capacitor by open-circuit and the
inductor by short-circuit. This shows that the final value is 1 V.
The initial conditions required for solving the differential equation are the values of capacitor
voltage at
t
=
0
+
and
of its first derivative at t
=
0
+
.
v
v
dv t
dt
i t
C
i t
v t
R
C
i
i
d
C
C
C
C
C
( )
( )
( )
( )
( )
( )
( )
( )
0
0
0
0
0
0
+
−
+
−
=
=
=
=
−
=
=
∴
vv t
dt
C
( )
(
)
0
0
+
=
Fig. 12.8-1
CircuitforExample:12.8-3
–
+
–
i
(
t
)
u
(
t
)
v
L
(
t
)
v
C
(
t
)
C
R
L
–
+
+
12.26
SeriesandParallel
RLC
Circuits
The step response for
v
C
(
t) will have the following format with
A
1
and
A
2
decided by initial
conditions.
v
C
(
t)
=
1
+
e
-
500
t
(
A
1
cos 2449.5
t
+
A
2
sin 2449.5
t ). Then,
v
C
‘
(
t)
=
-
500
e
-
500
t
(
A
1
cos 2449.5
t
+
A
2
sin 2449.5
t )
+
e
-
500
t
(
-
2449.5
A
1
sin 2449.5
t
+
2449.5
A
2
cos 2449.5
t)
Substituting
initial conditions,
A
1
=
-
1 and
-
500
A
1
+
2449.5
A
2
=
0
⇒
A
1
=
-
1 and
A
2
=
-
0.2041
\
Step response
v
C
(
t)
=
1
-
e
-
500
t
(cos 2449.5
t
+
0.2041 sin 2449.5
t )
=
[1 – 1.0206
e
-
500
t
cos (2449.5
t
-
0.2013 rad)] V for
t
≥
0
+
Rise time,
rad
t
r
n
=
−
−
−
=
−
×
=
−
p
x
x
x w
p
tan
.
.
.
1
2
2
1
1
1 37
0 978 2500
0 725 m
ms
Peak time,
ms
Settling time,
t
t
p
n
s
=
−
=
×
=
p
x w
p
1
0 978 2500
1 29
2
.
.
==
=
×
=
=
×
=
−
−
3
3
0 2 2500
6
100
1
2
xw
p x
x
n
p
M
e
.
ms
Percentage overshoot,
1100
52 6
0 6425
×
=
−
e
.
. %
12.9
Frequency reSponSe oF SerIeS
RLC
cIrcuIt
Consider a series
RLC circuit excited by a voltage source
v
S
(
t)
=
1 sin
w
t V for
t
≥
0
+
with a set of
specified initial conditions. We continue to use
v
C
(
t), the voltage across capacitor, as the describing
variable for the circuit.
The total response will contain natural response terms of exponentially damped sinusoidal nature
and forced response term. We expect the natural response terms to vanish when time increases without
limit. Only the forced response term acts in the long run, and of course,
it is termed steady-state
response. The sinusoidal steady-state response of series
RLC circuit in this section.
12.9.1
Sinusoidal Forced-response from differential equation
The differential equation governing
v
C
(
t), the capacitor voltage, in a series
RLC circuit excited by a
voltage source
v
S
(
t) was derived earlier in this chapter.
d v t
dt
dv t
dt
v t
v t
LC
R
L
C
n
C
n
C
n
S
n
2
2
2
2
2
1
2
( )
( )
( )
( )
,
+
+
=
=
=
xw
w
w
w
x
where
C
C
(12.9-1)
FrequencyResponseofSeries
RLC
Circuit
12.27
The steady-state component of response when
v
S
(
t)
=
1 sin
w
t u(
t) is obtained by ‘method of
undetermined coefficients’. We assume a trial solution of the form
v
C
(
t)
=
A sin
w
t
+
B cos
w
t and
determine the values of
A and
B by substituting the assumed solution in the differential equation and
equating coefficients of sin
w
t and cos
w
t on both sides of the resulting equation.
Trial
Solution,
Substituting in the
v t
A
t B
t
C
( )
sin
cos
=
+
w
w
differential equation and collecting terms,
(
)
w
w
n
2
2
−
A
A
B
t
B
A
t
t
n
n
n
n
−
+
−
+
=
2
2
2
2
2
xw
w
w
w
xw
w w
w
sin
(
)
cos
sin
The only way this equation can remain true independent of
t is by the coefficients of sin
w
t (and
cos
w
t ) becoming equal on both sides of the equation. Therefore,
(
)
(
)
w
w
xw
w
w
w
xw
n
n
n
n
n
A
B
B
A
2
2
2
2
2
2
2
0
−
−
=
−
+
=
.
Solving these two equations simultaneously we get,
A
B
n
n
n
n
n
n
n
=
−
−
+
=
−
−
+
w w
w
w
w
x w w
xw w w
w
w
x
2
2
2
2
2 2
2
2
2
2
2
2 2
2
4
2
4
(
)
(
)
,
(
)
(
)
w
w w
n
2
2
Substituting these in the assumed solution and simplifying the solution to a ‘single sinusoid with
phase’ form we get,
v t
t
C
n
n
n
C
n
n
( )
(
)
sin(
)
tan
=
−
+
+
= −
−
w
w
w
x w w
w f
f
xw w
w
2
2
2 2
2
2
2
1
4
2
C
where
22
2
−
w
(12.9-2)
Therefore, the magnitude part of the frequency-response
function for v
C
(
t) is
w
w
w
x w w
n
n
n
2
2
2 2
2
2
2
4
(
)
−
+
and the phase part of frequency-response function is
-
-
-
tan
1
2
2
2
xw w
w
w
n
n
.
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