chapter 1 network analysis
DESCRIPTION
jTRANSCRIPT
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Before solving exercise following terms should be kept in mind:
1. kirchhoffs current law
2. kirchhoffs voltage law
3. Loop analysis
4. Node analysis
5. Determinant
6. State variable analysis
7. Source transformation
1-5. Solution:
v = V0sint
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C = C0(1 - cost)
Q = I t
Q = CV
i = d(q)/dt = d(Cv)/dt = Cdv/dt + vdC/dt
i = Cdv/dt + vdC/dt
i = C0(1 - cost)d(V0sint)/dt + V0sintdC0(1 - cost)/dt
i = C0(1 - cost) V0cost + V0sint{C0sint}
1-10.
t
w = vi dt
-
For an inductor
vL = Ldi/dt
By putting the value of voltage
t
w = vi dt
-
t
w = (Ldi/dt)i dt
-
t
w = L idi
-
t
w = Li2/2
-
w = L[i2(t)/2 - i2(-)/2]
w = L[i2(t)/2 β (i(-))2/2]
w = L[i2(t)/2 β (0)2/2]
w = L[i2(t)/2] {Because i(-) = 0 for an inductor}
As we know
= Li
2 = L2i2
2/L = Li2
w = L[i2(t)/2]
w = Li2/2
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By putting the value of Li2
w = (2/L)/2
w = 2/2L {where = flux linkage}
1-11.
t
w = vi dt
-
For a capacitor
i = Cdv/dt
By putting the value of current
t
w = vi dt
-
t
w = (Cdv/dt)v dt
-
t
w = C vdv
-
t
w = Cv2/2
-
w = C[v2(t)/2 - v2(-)/2]
w = C[v2(t)/2 β (v(-))2/2]
w = C[v2(t)/2 β (0)2/2]
w = C[v2(t)/2] {Because v(-) = 0 for an inductor}
As we know
Q = CV
V = Q/C
w = C[v2(t)/2]
w = C[(q/C)2/2]
w = C[q2/2C2]
w = q2/2C
w = q2D/2 Ans.
1-12. wL = (1/2)Li2
P = vi
P = dwL/dt
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By putting values of P & wL
vi = d((1/2)Li2)/dt
vi = (1/2)dLi2/dt
vi = (1/2)Ldi2/dt
vi = (1/2)L2i{di/dt}
v = L{di/dt}
1-13.
wc = (1/2)Dq2
P = vi
P = dwL/dt
By putting values of P & wL
vi = d((1/2)Dq2)/dt
vi = (1/2)dDq2/dt
vi = (1/2)Ddq2/dt
vi = (1/2)D2q{dq/dt}
vi = Dq{dq/dt}
As we know
i = dq/dt
vi = Dq{dq/dt}
vi = Dq{i}
v = Dq
t
q = i dt
-
v = Dq
t
v = D i dt
-
1-17.
V = 12 V
C = 1F
w = ?
w = (1/2)CV2
= (1/2)(110-6)(12)2
w = 72J
1-18.
vc = 200 V
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C = 1F
mass = 100 lb = 45.3 kg
work done = Fd = mgd = (45.3)(9.8)d
work done = energy = (1/2)C(vc)2 = (1/2)(110-6)(200)2 = 0.02 joule
work done = (45.3)(9.8)d
0.02 = (45.3)(9.8)d
d = 0.02/(45.3)(9.8) = 0.02/443.94
d = 4.50510-5m Ans.
1-19.
Solution:
Vm
v
0 1 2 3 4 time
-Vm
for 0t1
(x1, y1) = (1, Vm)
(x0, y0) = (0, 0)
m = (y1 β y0)/(x1 β x0) = (Vm β 0)/(1 β 0)
m = Vm
y = mx + c = Vm(t) + 0 = Vmt
Slope = m
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for 1t3
Straight-line equation
y-intercept = c = 0
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(x1, y1) = (1, Vm)
m = (y3 β y1)/(x3 β x1) = (-Vm β Vm)/(3 - 1) = -2Vm/2 = -Vm
m = -Vm (x3, y3) = (3, -Vm)
y = mx + c = -Vm(t) + 2Vm = -Vmt + 2Vm
for 3t4
(x4, y4) = (4, 0)
(x3, y3) = (3, -Vm)
m = (y4 β y3)/(x4 β x3) = (0 β (-Vm))/(4 β 3)
m = Vm
y = mx + c = Vm(t) - 3Vm = Vmt β 3Vm
Slope = m
Straight-line equation
y-intercept = c = 2Vm
Slope = m
Straight-line equation
y-intercept = c = -3Vm
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i = CVm
Let capacitance be C
for 0t1
i = Cdv/dt = Cd(Vmt)/dt = CVm
i = CVm
for 1t3
i = Cdv/dt = Cd(-Vmt + 2Vm)/dt = -CVm
i = -CVm
for 3t4
i = Cdv/dt = Cd(Vmt β 3Vm)/dt = CVm
CVm
-CVm
for 0t1
q = CV
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q = CVmt
for 1t3
q = CV
q = CVm(2 β t)
for 3t4
q = CV
q = CVm(t - 4)
for 0t1 q = CVmt t = 0, q = 0 t = 1, q = CVm
for 1t3 q = CVm(2 β t) t = 3, q = -CVm
for 3t4 q = CVm(t - 4) t = 4, q = 0
Charge waveform same as voltage waveform.
(b)
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i(t)
0 1 2 3 4 time
for 0t1
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(x1, y1) = (1, Im)
(x0, y0) = (0, 0)
m = (y1 β y0)/(x1 β x0) = (Im β 0)/(1 β 0)
m = Im
y = mx + c = Im(t) + 0 = Imt
for 1t3
(x1, y1) = (1, Im)
m = (y3 β y1)/(x3 β x1) = (-Im β Im)/(3 - 1) = -2Im/2 = -Im
m = -Im (x3, y3) = (3, -Im)
y = mx + c = -Im(t) + 2Im = -Imt + 2Im
Slope = m
Straight-line equation
y-intercept = c = 0
Slope = m
Straight-line equation
y-intercept = c = 2Im
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for 3t4
(x4, y4) = (4, 0)
(x3, y3) = (3, -Im)
m = (y4 β y3)/(x4 β x3) = (0 β (-Im))/(4 β 3)
m = Im
y = mx + c = Im(t) - 3Im = Imt β 3Im
for 0t1
t
v(t) = (1/C)id(t) + v(t1)
t1
t
v(t) = (1/C)Imtd(t) + 0
0
t
v(t) = (1/C)Imtd(t)
0
t
v(t) = (1/C)Imt2/2
0
v(t) = (1/C)Im[(t2/2) - ((0)2/2)]
v(t) = (1/C)Im(t2/2)
v(1) = (1/C)Im((1)2/2) = (1/C)Im(1/2) = Im/2C
Slope = m
Straight-line equation
y-intercept = c = -3Im
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v(3) = (1/C)[(2(3) β (3)2/2) - (3/2)] + Im/2C
for 1t3
t
v(t) = (1/C)id(t) + v(t1)
t1
t
v(t) = (1/C)Im(2 β t)d(t) + Im/2C
1
t
v(t) = (1/C)2t β t2/2 + Im/2C
1
v(t) = (1/C)[(2t β t2/2) - (2(1) β 12/2)] + Im/2C
v(t) = (1/C)[(2t β t2/2) - (2 β 1/2)] + Im/2C
v(t) = (1/C)[(2t β t2/2) - (3/2)] + Im/2C
at time t = 3
v(3) = (1/C)[6 β 4.5 β 1.5] + Im/2C
v(3) = Im/2C
for 3t4
t
v(t) = (1/C)id(t) + v(3)
t1
t
v(t) = (1/C)Im(t - 3)d(t) + Im/2C
1
t
v(t) = (1/C)Imt2/2 β 3t + Im/2C
1
v(t) = (1/C)Im[(t2/2 β 3t) β (1/2 - 3)] + Im/2C
v(t) = (1/C)Im[(t2/2 β 3t) + 2.5] + Im/2C
at time t = 4
v(4) = (1/C)Im[((4)2/2 β 3(4)) + 2.5] + Im/2C
v(4) = (1/C)Im[16/2 β 12 + 2.5] + Im/2C
v(4) = (1/C)Im[8 β 12 + 2.5] + Im/2C
v(4) = (1/C)Im[β1.5] + Im/2C
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v(4) = -Im/C
v(0) 0
v(1) Im/2C = 0.5(Im/C)
v(2) Im2/C = 2(Im/C)
v(3) Im/2C = 0.5(Im/C)
v(4) -Im/C = -1(Im/C)
v(t) = (1/C)Im(t2/2)
at time t = 2
v(2) = (1/C)Im((2)2/2) = Im(2)/C
for 0t1
q = CV
1 2 3 4 5
Series2 0 0.5 2 0.5 -1
Series1 0 1 2 3 4
1
2
3
4
5
1
2
3
4
5
-2
-1
0
1
2
3
4
5
vo
ltag
e
time
Series2
Series1
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q = C(Imt2/2C) = Imt2/2
for 1t3
q = CV
q = CIm(4t β t2 - 2)/2C
for 3t4
q = CV
q = C(1/C)[Im[(t2/2 β 3t) + 2.5] + Im/2C] = Im[(t2/2 β 3t) + 2.5] + Im/2C
At time t = 0
q = C(Imt2/2C) = Imt2/2 = Im(0)2/2 = 0 C
At time t = 1
q = C(Imt2/2C) = Imt2/2 = Im12/2 = Im/2 C
At time t = 2
q = C(Imt2/2C) = Imt2/2 = Im22/2 = 2Im C
At time t = 3
q = CIm(4t β t2 - 2)/2C = CIm(4(3) β 32 - 2)/2C = (0.5Im/C) C
At time t = 4
q = C(1/C)[Im[(t2/2 β 3t) + 2.5] + Im/2C] = Im[(t2/2 β 3t) + 2.5] + Im/2C
q = Im[(42/2 β 3(4)) + 2.5] + Im/2C = -Im/C
Charge waveform same as voltage waveform.
1-20.
Solution:
I = 1A
L = Β½ H
wL = (1/2)LI2 = (1/2)(1/2)(1)2 = 0.25 J
As we know energy in an inductor = (1/2)LI2 J
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source
L
Short circuit
L
Energy will be lost after short-circuiting.
1-21.
Solution:
L = 1H
(a) (flux linkage) at t = 1sec.
(flux linkage) = LI
I = t {Because y = mx + c; m = 1 = slope}
(flux linkage) = Lt
at t = 1sec.
(flux linkage) = Lt = (1)(1) = 1 H(henry)A(ampere).
(b) d/dt = Ld(t)/dt = L = 1
(c)
t
q = idt
-
t
q = tdt
-
t
q = t2/2 = [t2/2 β (-)2/2] =
-
q = t2/2
1-24.
Solution:
+
-
At time t = 1sec q = t2/2 = q = (1)2/2 = Β½ Coulomb
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K is closed at t = 0
i(t) = 1 β e-t, t>0
i(t0) = 0.63 A
1 β e-t0 = 0.63 A
βe-t0 = -1 + 0.63 A
-e-t0 = -0.37
e-t0 = 0.37
Taking logarithm of both the sides
loge-t0 = log0.37
-t0loge = -0.432
t0(0.434) = 0.432 {Because e = 2.718}
t0 = 0.432/0.434 = 0.995 sec = 1 sec.
t0 = 1 sec.
(a) di(t0)/dt = ?
di(t)/dt = d(1 β e-t)/dt
di(t)/dt = d(1)/dt - d(e-t)/dt
di(t)/dt = 0 - e-t{d(-t)/dt}
di(t)/dt = 0 - e-t(-1)
di(t)/dt = e-t
di(t0)/dt = e-t0
t0 = 1 sec.
di(1)/dt = e-1
di(1)/dt = 1/e = Β½.718 = 0.37 Ampere per second
di(1)/dt = 1/e = Β½.718 = 0.37 Ampere per second
(b) = Li
i(t) = 1 β e-t
= Li(t)
= L(1 β e-t)
(t0) = L(1 β e-t0)
t0 = 1 sec
(1) = L(1 β e-1)
(1) = L(1 β 1/e)
As L = 1H & 1/e = 0.37
(1) = (1)(1 β 0.37) = 0.63 weber
(c) d/dt = ?
= L(1 β e-t) = = (1 β e-t)
d/dt = d(1 β e-t)/dt = d1/dt - de-t/dt = 0 + e-t = e-t
d/dt = e-t
d(t0)/dt = e-t0
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t0 = 1 sec.
d(1)/dt = e-1 = 1/e = 0.37 weber per sec.
(d)
v(t) = Ldi(t)/dt
i(t) = 1 β e-t & L = 1
v(t) = (1)d(1 β e-t)/dt
v(t) = d(1 β e-t)/dt = e-t
v(t0) = e-t0
t0 = 1 sec.
v(1) = e-1 = 1/e = 0.37 V
(e)
w = (1/2)Li2 = (1/2)(1)(1 β e-t)2
w = (1/2)(1 β e-t)2
w = (1/2)(1 + 2e-2t β 2e-t)
w(t0) = (1/2)(1 + 2e-2t0 β 2e-t0)
t0 = 1 sec.
w(1) = (1/2)(1 + 2e-2(1) β 2e-1)
w(1) = (1/2)(1 + 2e-2 β 2e-1)
w(1) = (1/2)(1 + 2(1/e2) β 2(1/e)) {1/e = 0.37; 1/e2 = 0.135}
w(1) = (1/2)(1 + 2(0.135) β 2(0.37))
w(1) = (1/2)(1 + 0.27 β 0.74)
w(1) = 0.265 Joule
(f)
vR = ?
vR = iR = (1 β e-t)(1) = (1 β e-t)
vR = iR = (1 β e-t)
vR(t0) = (1 β e-t0)
at time t0 = 1 sec.
vR(1) = (1 β e-1) = 0.63 V
(g)
w = (1/2)(1 + 2e-2t β 2e-t)
dw/dt = d((1/2)(1 + 2e-2t β 2e-t))/dt
dw/dt = (1/2)d(1 + 2e-2t β 2e-t)/dt
dw/dt = (1/2){d(1)/dt + d(2e-2t)/dt - d(2e-t)/dt}
dw/dt = (1/2){0 + 2e-2t)(-2) - 2e-t)(-1)}
dw/dt = (1/2){-4e-2t + 2e-t)}
dw(t0)/dt = (1/2){-4e-2t0 + 2e-t0)}
dw(1)/dt = (1/2){-4e-2 + 2e-1)}
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dw(1)/dt = (1/2){-4(1/e2) + 2(1/e)}
dw(1)/dt = (1/2){-4(0.135) + 2(0.37)}{1/e = 0.37; 1/e2 = 0.135}
dw(1)/dt = (1/2){-0.54 + 0.74} = 0.1 watts
(h)
PR = i2R = (1 + e-2t β 2e-t)(1)
PR = i2R = (1 + e-2t β 2e-t)
PR(t0) = i2R = (1 + e-2t0 β 2e-t0)
At time t0 = 1 sec.
PR(1) = i2R = (1 + e-2(1) β 2e-(1))
PR(1) = i2R = (1 + e-2 β 2e-1)
PR(1) = i2R = (1 + 1/e2 β 2(1/e))
PR(1) = i2R = (1 + 0.135 β 2(0.37))
PR(1) = i2R = (1 + 0.135 β 0.74)
PR(1) = i2R = (0.395) watts
(i)
Ptotal = vi = (1)(1 β e-t) = (1 β e-t)
At time t0 = 1 sec.
Ptotal(t0) = vi = (1)(1 β e-t) = (1 β e-t0)
Ptotal(1) = (1 β e-1)
Ptotal(1) = (1 β e-1) = 0.63 watts.
1-25.
Voltage across the capacitor at time t = 0
vc(0) = 1 Volt
k is closed at t = 0
i(t) = e-t, t>0
i(t0) = 0.37 A
0.37 = e-t0
Taking logarithm of both the sides
log0.37 = loge-t0
-t0loge = -0.432
t0(0.434) = 0.432 {Because e = 2.718}
t0 = 1 sec.
(a) dvc(t0)/dt = ?
Using loop equation
vc(t) = iR = e-t(1) = e-t Volts
dvc(t)/dt = -e-t Volts
dvc(t0)/dt = -e-t0 Volts
t0 = 1 sec.
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dvc(t0)/dt = -e-1 Volts
dvc(t0)/dt = -0.37 V/sec
(b)
Charge on the capacitor = q = Cv = (1)(e-t) = e-t coulomb
Charge on the capacitor = q(t0) = Cv = (1)(e-t) = e-t0 coulomb
t0 = 1 sec.
Charge on the capacitor = q(1) = Cv = (1)(e-t) = e-1 coulomb = 0.37 coulomb
(c) d(Cv)/dt = Cdv/dt = Cde-t/dt = -Ce-t
d(Cv(t0))/dt = -Ce-t0
t0 = 1 sec.
d(Cv(t0))/dt = -Ce-1
As C = 1F
d(Cv(t0))/dt = -e-1 = -0.37 coulomb/sec.
(d) vc(t) = e-t
t0 = 1 sec.
vc(t0) = e-t0
vc(1) = e-1 = 0.37 Volt
(e) wc = ?
wc = (1/2)Cv2 = (1/2)(1)(e-t)2 = (1/2)e-2t
wc(t0) = (1/2)Cv2 = (1/2)(1)(e-t0)2 = (1/2)e-2t0
t0 = 1 sec.
wc(1) = (1/2)e-2(1)
wc(1) = (1/2)e-2
wc(1) = (1/2)(1/e2) {1/e2 = 0.135}
wc(1) = (1/2)(0.135)
wc(1) = (1/2)(0.135) = 0.067 Joules
(f)
vR(t) = iR = e-t(1) = e-t Volts
vR(t0) = iR = e-t(1) = e-t0 Volts
t0 = 1 sec.
vR(1) = iR = e-t(1) = e-1 Volts = 0.37 Volts
(g) dwc/dt = ?
wc = (1/2)e-2t
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dwc/dt = d(1/2)e-2t/dt
dwc/dt = (1/2)e-2t(-2) = -e-2t
dwc(t0)/dt = (1/2)e-2t(-2) = -e-2t0
t0 = 1 sec.
dwc(1)/dt = (1/2)e-2t(-2) = -e-2(1)
dwc(1)/dt = (1/2)e-2t(-2) = -e-2
dwc(1)/dt = (1/2)e-2t(-2) = -e-2 = - 0.135 watts.
(h) P = i2R = (e-t)2(1) = e-2t
P(t0) = i2R = (e-t)2(1) = e-2t0
t0 = 1 sec.
P(1) = i2R = (e-t)2(1) = e-2(1)
P(1) = i2R = (e-t)2(1) = e-2
P(1) = i2R = (e-t)2(1) = e-2 = 0.135 watts.
1-26.
Solution:
(a) RC = (1/I)(q) = q/(q/t) = t
(b) L/R
V = Ldi/dt
L = V/(di/dt)
L = Vdt/di
R = V/I
L/R = (Vdt/di)/(V/I) = V2dt/Idi
(c)
LC = (Vdt/di)(q/V) = (dt/di)(q)
(d)
R2C = (V2/I2)(q/V) = Vq/I2 = V(It)/I2 = Vt/I
(e)
LC = (Vdt/di)/(q/V) = (V2dt)/(qdi) = (V2/di)/(1/(q/t))
(f)
L/R2 = = (Vdt/di)/(V2/I2) = Idt/V = q/V = C
1-39.
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1.0
vc(t)
sint
0.5
0 /6 /2 5/6
for vc -0.5Volt
C = (-1.0 + 0.5)/(-1.5 + 0.5) = -0.5/-1 = 0.5 F
for β0.5 vc 0.5
C = (0.5 + 0.5)/(0.5 + 0.5) = 1/1 = 1F
for 0.5 vc 1.5
C = (1.0 - 0.5)/(1.5 - 0.5) = 0.5/1 = 0.5F
for 0 vc 0.5 for 0 t /6
for 0.5 vc 1 for /6 t 5/6
for 0.5 vc 0 for 5/6 t
ic(t) = d(Cv)/dt = Cdv/dt + vdC/dt
ic(t) = Cdv/dt + vdC/dt
for 0 t /6
C = 1F
V = sint
ic(t) = (1)dsint/dt + sintd(1)/dt
ic(t) = cost
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ic(t) = d(Cv)/dt = Cdv/dt + vdC/dt
ic(t) = Cdv/dt + vdC/dt
for /6 t 5/6
C = 0.5F
v = sint
ic(t) = (0.5)dsint/dt + sintd(0.5)/dt
ic(t) = (0.5)cost
ic(t) = d(Cv)/dt = Cdv/dt + vdC/dt
ic(t) = Cdv/dt + vdC/dt
for 5/6 t
C = 1F
v = sint
ic(t) = (1)dsint/dt + sintd(1)/dt
ic(t) = cost
vc(t)
0 /6 /2 5/6
time
ic(t)
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0 /6 /2 5/6 time
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1-40.
0 1 2 3 4 time
0.25 0.25 0.25 0.25 0.25 0.25 0.25 0.25
2 2
4
vc(t) interval
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2t for 0 t 1
-2t + 4 for 1 t 2
2t β 4 for 02 t 3
-2t + 8 for 3 t 4
0 for t4
vc(t) interval Capacitor(value)
2t for 0 t 0.25
1F
2t for 0.25 t 1
0.5F
-2t + 4 for 1 t 1.75
0.5F
-2t + 4 for 1.75 t 2
1F
2t β 4 for 2 t 2.25
1F
2t β 4 for 2.25 t 3
0.5F
-2t + 8 for 3 t 3.75
0.5F
-2t + 8 for 3.75 t 4
1F
0 for t 4
1F
For the remaining part see 1-39 for reference.
1-27 β 1-38. (See chapter#3 for reference)
Before solving chapter#1 following points should be kept in mind:
1. Voltage across an inductor
2. Current through the capacitor
3. Graphical analysis
4. Power dissipation
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