TheParallel
RLC
Circuit
12.43
Solution (b)
The 25.3 mH inductor has a reactance of 2
p
×
10
3
×
25.3
×
10
-
3
=
159
W
at 1 kHz and since its
Q at
that frequency is given as 50, it has a series resistance of 159/50
=
3.18
W
. The function generator
that provides the square wave contributes 50
W
. Thus, the total series resistance in the series
RLC
circuit is 73.18
W
. The value of
f
n
of the circuit remains unchanged at 1 kHz. But its
x
factor becomes
0.23 now. Also, the total voltage that develops across 73.18
W
has to be multiplied by 20/73.18
=
0.273 to calculate the voltage across the load resistance. Thus, the frequency-response expression
now is
V j
V j
j
x
x
j
x
R
S
(
)
(
)
.
(
)
w
w
x
x
=
−
+
0 547
1
2
2
We continue to use
the same approximations for x >> 1.
The following table shows gain and phase of output for
x values from 1 to 11.
x
1
3
5
7
9
11
Gain
0.273
0.042
0.025
0.018
0.014
0.011
Phase(rad)
0
-
1.418
-
1.479
-
1.505
-
1.52
-
1.53
Now the first six terms of output may be constructed using the amplitude information.
v t
t
t
o
( )
=
×
+
×
−
+
0 273
2
10
0 014
6
10
1 418
0 005
10
3
3
.
sin
.
sin(
.
)
.
sin(
p
p
p
××
−
+
×
−
+
×
10
1 479
0 0026
14
10
1 505
0 0015
18
10
3
3
3
t
t
t
.
)
.
sin(
.
)
.
sin(
p
p
−−
+
×
−
1 52
0 001
22
10
1 53
3
. )
.
sin(
. )
p
t
Higher frequency terms are neglected. The output
waveforms for the two cases are plotted in Fig. 12.10-13.
The output in case (b) shows distortion clearly.
This example illustrates the importance of high quality
factor in filtering a square wave to a high
Q sine wave.
It also tells us that an otherwise high
Q factor circuit
may appear to be a low
Q circuit if we forget about the
output resistance of the signal
generator that we use
to test the circuit. The test signal should be passed on
to the test circuit through a unity gain buffer amplifier
with negligible output resistance.
12.11
the pArALLeL
RLC
cIrcuIt
We have dealt with the series
RLC circuit in great detail and have developed considerable insight into
the time-domain behaviour of second-order circuits in general. Moreover, we have also studied the
frequency-response of second-order circuits using series
RLC circuit as an example. This will help us
to draw parallels between the behaviour of series
RLC circuit with another equally important, if not
more important, circuit – the parallel
RLC circuit.
Fig. 12.10-13
Outputwaveforms
inExample:12.10-2
1
–1
0.2 0.4 0.6 0.8 1
Time
(ms)
v
o
(
t
)
(b)
(V)
(a)
12.44
SeriesandParallel
RLC
Circuits
Parallel
RLC circuit finds application in almost all communications equipment (starting from radio
receiver), sinusoidal oscillators, low-power and high-power filters and electrical power systems. In
fact, one can even state that analog communications will be impossible without using parallel
RLC
circuit
12.11.1
Zero-Input response and Zero-State response of parallel
RLC
circuit
Figure 12.11-1
shows a parallel RLC circuit excited
by a current source
i
S
(
t). There are four other circuit
variables apart from
i
S
(
t) – they are the three current
variables and one common voltage variable.
We choose
i
L
(
t) as the variable for deriving the
differential equation. However,
the variable that is
commonly used as output variable in practice is
v(
t).
All the three possible output voltage variables are used
in practical applications in the case of series
RLC circuit. But in the case of parallel
RLC circuit, it is
v(
t) that is almost used invariably. However,
v(
t) can be obtained easily once we solve for
i
L
(
t).
v t
L
di t
dt
i t
L
R
L
R
( )
( )
(
( )
=
∴
=
by element equation of inducatnce)
ddi t
dt
i t
LC
d i t
dt
L
C
L
( )
( )
( )
(
and
By element equations of R
=
2
2
aand C)
Now we apply KCL at the positive node of current source and make use of expressions for
i
C
(
t)
and
i
R
(
t) in terms of
i
L
(
t).
i t
i t
i t
i t
t
LC
d i t
dt
L
R
di t
dt
i
C
R
L
S
L
L
( )
( )
( )
( )
( )
( )
+
+
=
≥
∴
+
+
+
for
0
2
2
L
L
S
L
L
L
S
t
i t
t
d i t
dt
RC
di t
dt
LC
i t
LC
i
( )
( )
( )
( )
( )
(
=
≥
∴
+
+
=
+
for
0
1
1
1
2
2
tt
t
LC
RC
n
n
n
) for
and
are identified as
and 2
≥
=
=
⇒
+
0
1
1
x
w
w
xw
xx
=
=
=
1
2
1
2
L
C
cr
cr
L
C
R
R
R
R
Critical Resistance
Ω
We see that if we write the differential equations in
the standard format using
x
and
w
n
, the
differential equations for
v
C
(
t) in series
RLC circuit and i
L
(
t) in parallel
RLC Circuit are identical
except that
v
C
(
t)
gets replaced by i
L
(
t) and
v
S
(
t) gets replaced by
i
S
(
t). The only point we have to
remember is that the damping factor is
R
L C
/ 2
in the series
RLC circuit, whereas it is
1
2
L
C
R
for parallel
RLC Circuit. Thus, increasing resistance will increase damping in series
RLC circuit,
whereas it will decrease damping in parallel
RLC Circuit. The initial conditions needed for solving the
differential equation remain the same – inductor current
I
o
at
t
=
0
-
and
capacitor voltage V
o
at
t
=
0
-
.
The parallel
RLC circuit is over-damped for
x
> 1, critically damped for
x
=
1 and under-damped
for
x
< 1.
Fig. 12.11-1
Theparallel
RLC
circuit
–
R
C
L
+
i
S
(
t
)
i
R
(
t
)
i
L
(
t
)
i
C
(
t
)
v
(
t
)
TheParallel
RLC
Circuit
12.45
Zero-input response and zero-state response of parallel
RLC circuit is illustrated by a series of
examples that follow. The polarity conventions for specifying initial conditions is as per Fig. 12.11-1.
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