RESPONSE OF FIRST-ORDER RC AND RL CIRCUITS
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7.1 The Natural Response of an RC Circuit 7.2 The Natural Response of an RL Circuit 7.3 Singularity Functions 7.4 The Step Response of RC and RL Circuit
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�7.1 The Natural Response of an RC Circuit
Resistive Circuit => RC Circuit
algebraic equations => differential equations Same Solution Methods (a) Nodal Analysis (b) Mesh Analysis
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7.1 The Natural Response of an RC Circuit
The solution of a linear circuit, called dynamic response, can be decomposed into Natural Response + Forced Response or in the form of Steady Response + Transient Response
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�7.1 The Natural Response of an RC Circuit
The natural response is due to the initial condition of the storage component ( C or L). nThe forced response is resulted from external input ( or force). nIn this chapter, a constant input (DC input) will be considered and the forced response is called step response.
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7.1 The Natural Response of an RC Circuit
Example 1 : Two forms of the first order circuit for natural response
Find v(t)
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Find i(t)
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�7.1 The Natural Response of an RC Circuit
Example 1 : (cont.) Four forms of the first order circuit for step response
V R
TH
TH
A capacitor connected to a Thevenin equivalent
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A capacitor connected to a Norton equivalent
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7.1 The Natural Response of an RC Circuit
Example 1 : (cont.)
V R
TH
TH
An inductor connected to a Thevenin equivalent
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An inductor connected to a Norton equivalent
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�7.1 The Natural Response of an RC Circuit
Example 2
t0
nodal analysis ic + iR = 0 C
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dv 1 + v=0 dt R
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7.1 The Natural Response of an RC Circuit
Example 2 (cont.)
characteristic root S, 1 CS + = 0 R 1 S= RC v (t ) = Ke
1 t RC
t0
v ic v iR R
,t 0
From the initial condition v (0 + ) = v (0 - ) = V0
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v ( t ) = V0 e
t RC
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�7.1 The Natural Response of an RC Circuit
Example 2 (cont.)
= RC
t
time constant
v(t) = V0 e , t 0 t = , t = 3 , t = 5 ,
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v(t ) = 0.36788 V0 4.979% < 5% 0.674% < 1%
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7.1 The Natural Response of an RC Circuit
Example 2 (cont.)
It is customary to assume that the capacitor is fully discharged after five time constants.
v(t ) V0 iR (t ) = = e ,t 0 R R
The power dissipated in R is
V0 2 p (t ) = viR = e R
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2t
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�7.1 The Natural Response of an RC Circuit
Example 2 (cont.)
The energy dissipated in R is
1 wR (t ) = pdt = CV0 2 (1 e ) 2 0
2t
1 wR () = CV0 2 2
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7.1 The Natural Response of an RC Circuit
Example 3 : Find vc , vx , and ix for t > 0
This circuit contains only one energy storage element. Step 1. Use Thevenin theorem to find the equivalent RTH looking into a-b terminals.
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�7.1 The Natural Response of an RC Circuit
Example 3 : Find vc , vx , and ix for t > 0
Step 2. Find vc(t) Step 3. Replace vc(t) as a voltage source in the original circuit and solve the resistive circuit.
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7.1 The Natural Response of an RC Circuit
Step 1. RTH = (8 + 12) P 5 = 4
Step 2. vc (0) = 15V
0.1
dvc vc + =0 dt 4
2.5 t
= RC = 0.4 s vc (t) = 15e
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V, t 0
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�7.1 The Natural Response of an RC Circuit
Step 3.
By using voltage divider principle vx (t ) = 12 vc (t ) 8 + 12
2.5 t
= 9 e ix (t ) =
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V ,t 0
2.5 t vx (t ) = 0.75e A 12
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7.2 The Natural Response of an RL Circuit
Example 4
iL
Remember that vc(t) and iL(t) are continuous functions for bounded inputs. V t 0 , i = S = i (0 ) @ I0 RS
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�7.2 The Natural Response of an RL Circuit
t0
mesh analysis v L + vR = 0 L
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di + Ri = 0 dt
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7.2 The Natural Response of an RL Circuit
characteristic equation LS + R = 0 S = R L
i (t ) = Ke
R t L
,t 0
i (0 + ) = i (0 ) = I 0 i (t ) = I 0 e , t 0 @ L , time constant R
t
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�7.2 The Natural Response of an RL Circuit
vR (t ) = Ri = I0 Re pR = vR i = I0 Re
2
t
2 t
wR (t ) = wR () =
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1 pR (t )dt = LI0 2 (1 e ) 2
2 t
1 LI 0 2 2
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7.2 The Natural Response of an RL Circuit
Example 5 : i(0)=10A , find i(t) and ix(t)
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�7.2 The Natural Response of an RL Circuit
Step 1. Find the Thevenin equivalent circuit looking into a-b terminals. Apply is , find e. Then RTH = e / is
i = is e 3i e + = is 4 2 e 3 e + is + = is 4 4 2
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7.2 The Natural Response of an RL Circuit
3 1 e = is 4 4 e 1 = is 3
Step 2.
1 3
mesh equation di 1 + i=0 dt 3 L 0.5 = = = 1.5 S R 1/ 3 0.5 i (t)=10e A , t 0
2 - t 3
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�7.2 The Natural Response of an RL Circuit
Step 3 Replace the inductor with an equivalent current source with i(t) and solve the resistive circuit.
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i (t) = 10 e
-2 t 3
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7.2 The Natural Response of an RL Circuit
For this problem, since 2 is in parallel with the inductor, it is trivial to get
vL (t) = L di dt
t d (10 e 3 ) dt -2
= 0.5
= 0.5 10 (
-2
-2 3 t )e 3
-2
-10 3 t e V 3 -2 v -5 3 t ix = L = e V, t0 2 3 =
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�7.2 The Natural Response of an RL Circuit
Example 6 : The switch has been closed for a long time. At t=0, it is opened. Find ix .
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7.2 The Natural Response of an RL Circuit
t=0-
i1 (0- ) =
40V =8A 2+(12//4)
ix (0- ) = 0 12 3 = 8 = 6 A 12+4 4 + Initial codition i (0 ) = i (0- ) = 6 A i (0- ) = i1 (0- )
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�7.2 The Natural Response of an RL Circuit
t 0+
Step 1 RTH = (4+12) // 16 = 8
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7.2 The Natural Response of an RL Circuit
Step 2 mesh analysis
di + 8i = 0 dt i (t) = K e-4t , t 0 2 i (0+ ) = 6 A i (t) = 6 e-4t A , t 0
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�7.2 The Natural Response of an RL Circuit
Step 3 Replace L with an equivalent current source, and find ix solve the resistive circuit.
ix (t) =
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4+12 i (t) 12+4+16 = 3e-4t A , t 0
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7.3 Singularity Functions
Switching functions are convenient for describing the switching actions in circuit analysis. They serve as good approximations to the switching signals.
unit step function unit impulse function unit ramp function
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u(t) (t) r(t)
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�7.3 Singularity Functions
Definition 0 , t<0 u(t) = 1 , t>0 undefined at t=0 or more general 0 , t<t 0 u(t-t 0 ) = 1 , t>t 0
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Example 7
V0 u(t-t0) is applied to a-b terminals
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7.3 Singularity Functions
Definition d (t) = u(t) = dt , t<0 0 undefined , t=0 0 , t>0
Also known as the delta function
or
(t) dt = 1 (t-t 0 ) dt = 1
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0+ 0-
or
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t 0+ t 0-
�7.3 Singularity Functions
The unit impulse function is not physically realizable but is a very useful mathematical tool.
1 2d
An approximation as d 0
1 d
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Another approximation as d 0
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7.3 Singularity Functions
Shifting property, if t 0 [a , b]
a f(t) (t-t 0 )dt = f(t 0 )
b
Q a f(t) (t-t 0 )dt = a f(t 0 ) (t-t 0 )dt
b b
= f(t 0 )a (t-t 0 )dt
b
= f(t 0 )
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�7.3 Singularity Functions
Definition r(t) = - u(t)dt = t u(t) or 0 , r(t) = t , t0 t0
t
Note that (t) = d u(t) dt d r(t) u(t) = dt , , u(t) = (t)dt
t
r(t) = u(t)dt
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7.3 Singularity Functions
Example 8
(a)
v(t) = 10 [u(t-2) - u(t-5)]
(b )
dv(t) = 10 (t-2) - 10 (t-5) dt
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�7.3 Singularity Functions
(c )
i(t) = 10 u(t) -20 u(t-2)+10u(t-4)
(d )
v(t) = 5r (t)-5r (t-2)-10u(t-2)
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7.4 The Step Response of RC and RL Circuits
When a dc voltage (current) source is suddenly applied to a circuit , it can be modeled as a step function , and the resulting response is called step response .
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�7.4 The Step Response of RC and RL Circuits
Example 9
V ( 0 ) = V0 , i = C
dv , choose v as unknown dt
Step 1
Mesh Analysis dv RC + v = VS , t 0 dt
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7.4 The Step Response of RC and RL Circuits
Step 2 Solving the differential equation ( a ) homogeneous solution
RC
dv h + vh = 0 dt
t RC
v h ( t ) = Ke dv p
, t0
( b ) particular solution dt v p = VS RC + v p = VS
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�7.4 The Step Response of RC and RL Circuits
(c) co m p lete so lu tio n + In itial co n d itio n v ( t ) = vh + v p v (0 + ) = v (0 ) = V0 K = V0 Vs V 0 , t < 0 v (t ) = t V s + (V 0 V s ) e , t 0
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= Ke
t RC
+ Vs
7.4 The Step Response of RC and RL Circuits
Vs R
i(t)
t dv 1 RC i(t ) = C = C(Vo Vs )( )e dt RC t Vs Vo RC = e , t 0 R V For Vo = 0 , then i(o+ ) = S R C is initially short circuited.
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�7.4 The Step Response of RC and RL Circuits
Example 10
Before t=0 , the circuit is under steady state . At t=0 , the switch is moved to B . Find v(t) , t > 0 For t<0 , the circuit shown:
v ( 0 ) =
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3k
4k
5k
3k
5 24V = 15V 3+5
5k
v(0 )
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7.4 The Step Response of RC and RL Circuits
For t>0
mesh analysis
4k
dv 4 10 3 ( 0.5 10 3 ) + v = 30V dt v ( t ) = v p + vh = 30 + Ke
t 3
, t>0
= RC = 4 10 0.5 10 3 = 2 second v ( 0 + ) = v ( 0 ) = 15V
t
v ( t ) = 30 + (15 30 ) e
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,t0
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�7.4 The Step Response of RC and RL Circuits
Example 11
Before the switch is open at t=0, the circuit is in steady state. Find i(t) & v(t) for all t. For t<0 , then
v ( t ) = 10V , t < 0 10 i ( t ) = A = 1A , t < 0 10
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10
20
1 F 4
10
20
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7.4 The Step Response of RC and RL Circuits
For t>0
1 F 4
Thevenin equivalent circuit
20 3
1 F 4
v ( 0+ ) = v ( 0 ) = 10V
ic ( t ) = C
dv 1 dv = dt 4 dt 20 1 dv + v = 20V , t > 0 3 4 dt
3 t 5
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v ( t ) = 20 + Ke
= 20 + (10 20 ) e
3 t 5
,t > 0
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�7.4 The Step Response of RC and RL Circuits
From the original circuit v dv +C KCL : i (t ) = dt 20 0.6 t = 1+ e ,t > 0 10V , t < 0 v (t ) = 0.6 t )V , t 0 ( 20 10 e 1 A, t < 0 i (t ) = 0.6 t ) A, t 0 (1 + e Note that
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i (0 ) = 1 A i (0 + ) = 2 A
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7.4 The Step Response of RC and RL Circuits
Example 12
Mesh analysis di L + RTH i = VTH , t 0 dt i ( 0) = 0
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�7.4 The Step Response of RC and RL Circuits
Solution:
i(t ) = ih (t ) + i p (t ) characteristic equation LS + RTH = 0 R 1 S = TH = L ih (t ) = Ke
t
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i p (t ) =
VTH RTH
t VTH + Ke RTH + i(0 ) = i(0 ) = 0 Note : L is equivalent to open circuit t V i(t ) = TH (1 e ) , t 0 RTH t di V (t ) = L = VTH e u(t ) dt
i(t ) =
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7.4 The Step Response of RC and RL Circuits
t VTH i (t ) = (1 e ) , t 0 RTH
V (t ) = L
t di = VTH e u (t ) dt
VTH RTH
VTH
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�7.4 The Step Response of RC and RL Circuits
Example 13
t0 , steady state
1 H 3
t0 , switch is opened
For t<0
i (0) =
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10 = 5A 2
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7.4 The Step Response of RC and RL Circuits
For t 0
1 H 3
Mesh Analysis 1 di + 5i = 10V , t 0 3 dt s = 15 ih (t ) = Ke
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1 H 3
i (t ) = ih + i p = Ke
t
+ 2A , t 0
, =
1 15
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i p (t ) = 2 A
�7.4 The Step Response of RC and RL Circuits
initial condition i (0+ ) = i (0 ) = 5 A
i (t ) = 2 + 3e
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,t0
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7.4 The Step Response of RC and RL Circuits
Note that if V is chosen for solution : V ( 0 ) = 0V KVL : V (0+ ) = 10V (2 + 3)5 = 15V
t di 1 d or V = L = (2 + 3e ) dt 3 dt 1 t = e , t 0+ + V (0 ) = 15V , same answer.
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�7.4 The Step Response of RC and RL Circuits
Example 14 : S1 is closed at t=0
S2 is closed at t=4 Find i(2)= i(5)=?
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7.4 The Step Response of RC and RL Circuits
For t < 0
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t < 0 , i=0 , open circuit
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�7.4 The Step Response of RC and RL Circuits
For 0+ t 4S
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7.4 The Step Response of RC and RL Circuits
For 0+ t 4S
di + 10i = 40V , 0+ t 4S dt i (0 + ) = i (0 ) = 0 A =
L 5 1 = = R 10 2 i (t ) = 4(1 e 2 t ) A , 0 + t 4 S
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i (4 ) = 4(1 e 8t ) 4 A
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�7.4 The Step Response of RC and RL Circuits
For t 4+
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7.4 The Step Response of RC and RL Circuits
For t 4+
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i (4 ) = 4 A 40 10 VTH = 2 + 10 = 20V 4+2 4 22 RTH = 4 P 2 + 6 = + 6 = 3 3 L 5 15 = = = S RTH 22 / 3 22
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�7.4 The Step Response of RC and RL Circuits
For t 4+
22 3
i (4 + ) = i ( 4 ) = 4 A 5 di 22 + i = 20V dT 3 where T = t 4
22 (t 4 ) 15
ih (t ) = Ke
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, t 4+
i p (t ) =
20 60 30 = = = 2.727 22 / 3 22 11
22 (t 4) 30 + Ke 15 , t 4+ 11 30 i (4 + ) = 4 A = +K 11 30 14 K = 4 = 11 11 22 30 14 15 ( t 4 ) i (t ) = + e , t 4+ 11 11
i (t ) =
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7.4 The Step Response of RC and RL Circuits
In Summary 0 , t 0 i (t ) = 4(1 e 2t ) , 0 t 4 30 14 + e 22(t 4) , t 4 11 11
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�Summary
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Objective 1 : Be able to determine the natural response of both RC and RL circuits. Objective 2 : Be able to find the step response of both RC and RL circuits. Objective 3 : Know and be able to use the singularity functions. Objective 4 : Be able to analyze circuits with sequential switching.
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Summary
Chapter Problems : 7.7
7.14 7.23 7.32 7.47 7.63
Due within one week.
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