Find the output voltage when the input voltage v i ( t ) = 4 e − t u ( t ) V

Question

Want to see more full solutions like this?

Answer 1

Question

Chapter 18, Problem 59P

To determine

Find the output voltage when the input voltage vi(t)=4e−tu(t) V

Expert Solution & Answer

Answer to Problem 59P

The output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Explanation of Solution

Given data:

vi(t)=2δ(t) V (1)

vo(t)=10e−2t−6e−4t V (2)

Formula used:

Consider the general expression for transfer function.

H(ω)=Vo(ω)Vi(ω) (3)

Here,

Vo(ω) is the output voltage.

Vi(ω) is the input voltage.

Calculation:

Apply Fourier transform on both sides of equation (1) as follows.

F[vi(t)]=F[2δ(t)]Vi(ω)=2

Apply Fourier transform on both sides of equation (2) as follows.

F[vo(t)]=F[10e−2t−6e−4t]Vo(ω)=F[10e−2t]−F[6e−4t]Vo(ω)=102+jω−64+jω

Substitute 2 for Vi(ω) and 102+jω−64+jω for Vo(ω) in equation (3) as follows.

H(ω)=(102+jω−64+jω)2=52+jω−34+jω

Consider vi(t)=4e−tu(t) V.

Apply Fourier transform on both sides of equation as follows.

F[vi(t)]=F[4e−tu(t)]Vi(ω)=41+jω

Rearrange equation (3) as follows.

Vo(ω)=H(ω)Vi(ω)

Substitute (52+jω−34+jω) for H(ω) and 41+jω for Vi(ω) as follows.

Vo(ω)=(52+jω−34+jω)(41+jω)=20(2+jω)(1+jω)−12(4+jω)(1+jω)

Consider s=jω to reduce complex algebra.

Substitute s for jω as follows.

Vo(s)=20(2+s)(1+s)−12(4+s)(1+s)

Consider Vo(s)=V1(s)−V2(s) (4)

Here,

V1(s)=20(2+s)(1+s)V2(s)=12(4+s)(1+s)

Take partial fraction for V1(s).

V1(s)=A1+s+B2+s (5)

Where,

A=(s+1)V1(s)|s=−1

Substitute 20(2+s)(1+s) for V1(s) as follows.

A=(s+1)[20(2+s)(1+s)]s=−1=[20(2+s)]s=−1=[201]=20

Similarly,

B=(s+2)V1(s)|s=−2

Substitute 20(2+s)(1+s) for V1(s) as follows.

B=(s+2)[20(2+s)(1+s)]s=−2=[201+s]s=−2=[20−1]=−20

Substitute 20 for A and −20 for B in equation (5) as follows.

V1(s)=201+s−202+s

Take partial fraction for V2(s).

V2(s)=C1+s+D4+s (6)

Where,

C=(s+1)V2(s)|s=−1

Substitute 12(4+s)(1+s) for V2(s) as follows.

C=(s+1)[12(4+s)(1+s)]s=−1=[124+s]s=−1=[123]=4

Similarly,

D=(s+4)V2(s)|s=−4

Substitute 12(4+s)(1+s) for V2(s) as follows.

D=(s+4)[12(4+s)(1+s)]s=−4=[121+s]s=−4=12−3=−4

Substitute 4 for C and −4 for D in equation (6) as follows.

V2(s)=41+s−44+s

Substitute 201+s−202+s for V1(s) and 41+s−44+s for V2(s) in equation (4) as follows.

Vo(s)=[201+s−202+s]−[41+s−44+s]=201+s−202+s−41+s+44+s=161+s−202+s+44+s

Substitute jω for s as follows.

Vo(ω)=16jω+1−20jω+2+4jω+4

Apply inverse Fourier transform on both sides of equation.

F−1[Vo(ω)]=F−1[16jω+1−20jω+2+4jω+4]vo(t)=F−1[16jω+1]−F−1[20jω+2]+F−1[4jω+4]vo(t)=16e−tu(t)−20e−2tu(t)+4e−4tu(t)vo(t)=(16e−t−20e−2t+4e−4t)u(t)

Conclusion:

Thus, the output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Students have asked these similar questions

The short-circuit test has been carried out on a single-phase transformer of 2500kVA,50kV/10kV, with the following results: 4000V, 50A , 50000 WIt is known that the transformer has a vacuum current equal to 2% and its efficiency at full load fp=1 is 97.5%. Calculate: A. Parameters of the excitation branch. Rfe, JXm, Pob. Relative voltage drops. εcc, εrcc, εxcc

Magnetic Field Analysis of a Helical Coil In this lab you will analyse the inductive coil structure shown in Figure 1. It comprises a solid round copper wire of radius a = 0.8mm, wound into a cylindrical spiral having N = 20 turns, major radius R = 10mm and an axial pitch p = 2mm. The coil is excited by a dc current of 1A. R P 1 (a) Analytic Calculations Figure 1: Helical Air-cored Coil Using the expressions developed in the class, estimate the magnetic flux density B at the centre of the coil. Recall from EN1216 that for a long solenoid, the flux density is given by: HONI B l As we saw in the class (see section 4) a modified expression can also be derived that eliminates the need for the 'long' solenoid assumption: R α1 Р â B = HONI 2l (cosa₂-cosα1) 1 Compare the results obtained using equations (1) and (2) and state which solution you would expect to give the best approximation to the real coil behaviour.

I need immediate help with my SIMULINK model. I don't know why but no matter how much a increase or decrease Kc or TI, the graphs are the same. C'A0(s) is the disturbance going through G'D(s). Please check my transfer function blocks by taking the laplace transform of the equations. Any suggestions is welcome greatly! thanks

Answer 2

Question

Chapter 18, Problem 59P

To determine

Find the output voltage when the input voltage vi(t)=4e−tu(t) V

Expert Solution & Answer

Answer to Problem 59P

The output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Explanation of Solution

Given data:

vi(t)=2δ(t) V (1)

vo(t)=10e−2t−6e−4t V (2)

Formula used:

Consider the general expression for transfer function.

H(ω)=Vo(ω)Vi(ω) (3)

Here,

Vo(ω) is the output voltage.

Vi(ω) is the input voltage.

Calculation:

Apply Fourier transform on both sides of equation (1) as follows.

F[vi(t)]=F[2δ(t)]Vi(ω)=2

Apply Fourier transform on both sides of equation (2) as follows.

F[vo(t)]=F[10e−2t−6e−4t]Vo(ω)=F[10e−2t]−F[6e−4t]Vo(ω)=102+jω−64+jω

Substitute 2 for Vi(ω) and 102+jω−64+jω for Vo(ω) in equation (3) as follows.

H(ω)=(102+jω−64+jω)2=52+jω−34+jω

Consider vi(t)=4e−tu(t) V.

Apply Fourier transform on both sides of equation as follows.

F[vi(t)]=F[4e−tu(t)]Vi(ω)=41+jω

Rearrange equation (3) as follows.

Vo(ω)=H(ω)Vi(ω)

Substitute (52+jω−34+jω) for H(ω) and 41+jω for Vi(ω) as follows.

Vo(ω)=(52+jω−34+jω)(41+jω)=20(2+jω)(1+jω)−12(4+jω)(1+jω)

Consider s=jω to reduce complex algebra.

Substitute s for jω as follows.

Vo(s)=20(2+s)(1+s)−12(4+s)(1+s)

Consider Vo(s)=V1(s)−V2(s) (4)

Here,

V1(s)=20(2+s)(1+s)V2(s)=12(4+s)(1+s)

Take partial fraction for V1(s).

V1(s)=A1+s+B2+s (5)

Where,

A=(s+1)V1(s)|s=−1

Substitute 20(2+s)(1+s) for V1(s) as follows.

A=(s+1)[20(2+s)(1+s)]s=−1=[20(2+s)]s=−1=[201]=20

Similarly,

B=(s+2)V1(s)|s=−2

Substitute 20(2+s)(1+s) for V1(s) as follows.

B=(s+2)[20(2+s)(1+s)]s=−2=[201+s]s=−2=[20−1]=−20

Substitute 20 for A and −20 for B in equation (5) as follows.

V1(s)=201+s−202+s

Take partial fraction for V2(s).

V2(s)=C1+s+D4+s (6)

Where,

C=(s+1)V2(s)|s=−1

Substitute 12(4+s)(1+s) for V2(s) as follows.

C=(s+1)[12(4+s)(1+s)]s=−1=[124+s]s=−1=[123]=4

Similarly,

D=(s+4)V2(s)|s=−4

Substitute 12(4+s)(1+s) for V2(s) as follows.

D=(s+4)[12(4+s)(1+s)]s=−4=[121+s]s=−4=12−3=−4

Substitute 4 for C and −4 for D in equation (6) as follows.

V2(s)=41+s−44+s

Substitute 201+s−202+s for V1(s) and 41+s−44+s for V2(s) in equation (4) as follows.

Vo(s)=[201+s−202+s]−[41+s−44+s]=201+s−202+s−41+s+44+s=161+s−202+s+44+s

Substitute jω for s as follows.

Vo(ω)=16jω+1−20jω+2+4jω+4

Apply inverse Fourier transform on both sides of equation.

F−1[Vo(ω)]=F−1[16jω+1−20jω+2+4jω+4]vo(t)=F−1[16jω+1]−F−1[20jω+2]+F−1[4jω+4]vo(t)=16e−tu(t)−20e−2tu(t)+4e−4tu(t)vo(t)=(16e−t−20e−2t+4e−4t)u(t)

Conclusion:

Thus, the output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Question

Chapter 18, Problem 59P

To determine

Find the output voltage when the input voltage vi(t)=4e−tu(t) V

Expert Solution & Answer

Answer to Problem 59P

The output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Explanation of Solution

Given data:

vi(t)=2δ(t) V (1)

vo(t)=10e−2t−6e−4t V (2)

Formula used:

Consider the general expression for transfer function.

H(ω)=Vo(ω)Vi(ω) (3)

Here,

Vo(ω) is the output voltage.

Vi(ω) is the input voltage.

Calculation:

Apply Fourier transform on both sides of equation (1) as follows.

F[vi(t)]=F[2δ(t)]Vi(ω)=2

Apply Fourier transform on both sides of equation (2) as follows.

F[vo(t)]=F[10e−2t−6e−4t]Vo(ω)=F[10e−2t]−F[6e−4t]Vo(ω)=102+jω−64+jω

Substitute 2 for Vi(ω) and 102+jω−64+jω for Vo(ω) in equation (3) as follows.

H(ω)=(102+jω−64+jω)2=52+jω−34+jω

Consider vi(t)=4e−tu(t) V.

Apply Fourier transform on both sides of equation as follows.

F[vi(t)]=F[4e−tu(t)]Vi(ω)=41+jω

Rearrange equation (3) as follows.

Vo(ω)=H(ω)Vi(ω)

Substitute (52+jω−34+jω) for H(ω) and 41+jω for Vi(ω) as follows.

Vo(ω)=(52+jω−34+jω)(41+jω)=20(2+jω)(1+jω)−12(4+jω)(1+jω)

Consider s=jω to reduce complex algebra.

Substitute s for jω as follows.

Vo(s)=20(2+s)(1+s)−12(4+s)(1+s)

Consider Vo(s)=V1(s)−V2(s) (4)

Here,

V1(s)=20(2+s)(1+s)V2(s)=12(4+s)(1+s)

Take partial fraction for V1(s).

V1(s)=A1+s+B2+s (5)

Where,

A=(s+1)V1(s)|s=−1

Substitute 20(2+s)(1+s) for V1(s) as follows.

A=(s+1)[20(2+s)(1+s)]s=−1=[20(2+s)]s=−1=[201]=20

Similarly,

B=(s+2)V1(s)|s=−2

Substitute 20(2+s)(1+s) for V1(s) as follows.

B=(s+2)[20(2+s)(1+s)]s=−2=[201+s]s=−2=[20−1]=−20

Substitute 20 for A and −20 for B in equation (5) as follows.

V1(s)=201+s−202+s

Take partial fraction for V2(s).

V2(s)=C1+s+D4+s (6)

Where,

C=(s+1)V2(s)|s=−1

Substitute 12(4+s)(1+s) for V2(s) as follows.

C=(s+1)[12(4+s)(1+s)]s=−1=[124+s]s=−1=[123]=4

Similarly,

D=(s+4)V2(s)|s=−4

Substitute 12(4+s)(1+s) for V2(s) as follows.

D=(s+4)[12(4+s)(1+s)]s=−4=[121+s]s=−4=12−3=−4

Substitute 4 for C and −4 for D in equation (6) as follows.

V2(s)=41+s−44+s

Substitute 201+s−202+s for V1(s) and 41+s−44+s for V2(s) in equation (4) as follows.

Vo(s)=[201+s−202+s]−[41+s−44+s]=201+s−202+s−41+s+44+s=161+s−202+s+44+s

Substitute jω for s as follows.

Vo(ω)=16jω+1−20jω+2+4jω+4

Apply inverse Fourier transform on both sides of equation.

F−1[Vo(ω)]=F−1[16jω+1−20jω+2+4jω+4]vo(t)=F−1[16jω+1]−F−1[20jω+2]+F−1[4jω+4]vo(t)=16e−tu(t)−20e−2tu(t)+4e−4tu(t)vo(t)=(16e−t−20e−2t+4e−4t)u(t)

Conclusion:

Thus, the output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Question

Chapter 18, Problem 59P

To determine

Find the output voltage when the input voltage vi(t)=4e−tu(t) V

Expert Solution & Answer

Answer to Problem 59P

The output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Explanation of Solution

Given data:

vi(t)=2δ(t) V (1)

vo(t)=10e−2t−6e−4t V (2)

Formula used:

Consider the general expression for transfer function.

H(ω)=Vo(ω)Vi(ω) (3)

Here,

Vo(ω) is the output voltage.

Vi(ω) is the input voltage.

Calculation:

Apply Fourier transform on both sides of equation (1) as follows.

F[vi(t)]=F[2δ(t)]Vi(ω)=2

Apply Fourier transform on both sides of equation (2) as follows.

F[vo(t)]=F[10e−2t−6e−4t]Vo(ω)=F[10e−2t]−F[6e−4t]Vo(ω)=102+jω−64+jω

Substitute 2 for Vi(ω) and 102+jω−64+jω for Vo(ω) in equation (3) as follows.

H(ω)=(102+jω−64+jω)2=52+jω−34+jω

Consider vi(t)=4e−tu(t) V.

Apply Fourier transform on both sides of equation as follows.

F[vi(t)]=F[4e−tu(t)]Vi(ω)=41+jω

Rearrange equation (3) as follows.

Vo(ω)=H(ω)Vi(ω)

Substitute (52+jω−34+jω) for H(ω) and 41+jω for Vi(ω) as follows.

Vo(ω)=(52+jω−34+jω)(41+jω)=20(2+jω)(1+jω)−12(4+jω)(1+jω)

Consider s=jω to reduce complex algebra.

Substitute s for jω as follows.

Vo(s)=20(2+s)(1+s)−12(4+s)(1+s)

Consider Vo(s)=V1(s)−V2(s) (4)

Here,

V1(s)=20(2+s)(1+s)V2(s)=12(4+s)(1+s)

Take partial fraction for V1(s).

V1(s)=A1+s+B2+s (5)

Where,

A=(s+1)V1(s)|s=−1

Substitute 20(2+s)(1+s) for V1(s) as follows.

A=(s+1)[20(2+s)(1+s)]s=−1=[20(2+s)]s=−1=[201]=20

Similarly,

B=(s+2)V1(s)|s=−2

Substitute 20(2+s)(1+s) for V1(s) as follows.

B=(s+2)[20(2+s)(1+s)]s=−2=[201+s]s=−2=[20−1]=−20

Substitute 20 for A and −20 for B in equation (5) as follows.

V1(s)=201+s−202+s

Take partial fraction for V2(s).

V2(s)=C1+s+D4+s (6)

Where,

C=(s+1)V2(s)|s=−1

Substitute 12(4+s)(1+s) for V2(s) as follows.

C=(s+1)[12(4+s)(1+s)]s=−1=[124+s]s=−1=[123]=4

Similarly,

D=(s+4)V2(s)|s=−4

Substitute 12(4+s)(1+s) for V2(s) as follows.

D=(s+4)[12(4+s)(1+s)]s=−4=[121+s]s=−4=12−3=−4

Substitute 4 for C and −4 for D in equation (6) as follows.

V2(s)=41+s−44+s

Substitute 201+s−202+s for V1(s) and 41+s−44+s for V2(s) in equation (4) as follows.

Vo(s)=[201+s−202+s]−[41+s−44+s]=201+s−202+s−41+s+44+s=161+s−202+s+44+s

Substitute jω for s as follows.

Vo(ω)=16jω+1−20jω+2+4jω+4

Apply inverse Fourier transform on both sides of equation.

F−1[Vo(ω)]=F−1[16jω+1−20jω+2+4jω+4]vo(t)=F−1[16jω+1]−F−1[20jω+2]+F−1[4jω+4]vo(t)=16e−tu(t)−20e−2tu(t)+4e−4tu(t)vo(t)=(16e−t−20e−2t+4e−4t)u(t)

Conclusion:

Thus, the output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Chapter 18, Problem 59P

To determine

Find the output voltage when the input voltage vi(t)=4e−tu(t) V

Expert Solution & Answer

Answer to Problem 59P

The output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Explanation of Solution

Given data:

vi(t)=2δ(t) V (1)

vo(t)=10e−2t−6e−4t V (2)

Formula used:

Consider the general expression for transfer function.

H(ω)=Vo(ω)Vi(ω) (3)

Here,

Vo(ω) is the output voltage.

Vi(ω) is the input voltage.

Calculation:

Apply Fourier transform on both sides of equation (1) as follows.

F[vi(t)]=F[2δ(t)]Vi(ω)=2

Apply Fourier transform on both sides of equation (2) as follows.

F[vo(t)]=F[10e−2t−6e−4t]Vo(ω)=F[10e−2t]−F[6e−4t]Vo(ω)=102+jω−64+jω

Substitute 2 for Vi(ω) and 102+jω−64+jω for Vo(ω) in equation (3) as follows.

H(ω)=(102+jω−64+jω)2=52+jω−34+jω

Consider vi(t)=4e−tu(t) V.

Apply Fourier transform on both sides of equation as follows.

F[vi(t)]=F[4e−tu(t)]Vi(ω)=41+jω

Rearrange equation (3) as follows.

Vo(ω)=H(ω)Vi(ω)

Substitute (52+jω−34+jω) for H(ω) and 41+jω for Vi(ω) as follows.

Vo(ω)=(52+jω−34+jω)(41+jω)=20(2+jω)(1+jω)−12(4+jω)(1+jω)

Consider s=jω to reduce complex algebra.

Substitute s for jω as follows.

Vo(s)=20(2+s)(1+s)−12(4+s)(1+s)

Consider Vo(s)=V1(s)−V2(s) (4)

Here,

V1(s)=20(2+s)(1+s)V2(s)=12(4+s)(1+s)

Take partial fraction for V1(s).

V1(s)=A1+s+B2+s (5)

Where,

A=(s+1)V1(s)|s=−1

Substitute 20(2+s)(1+s) for V1(s) as follows.

A=(s+1)[20(2+s)(1+s)]s=−1=[20(2+s)]s=−1=[201]=20

Similarly,

B=(s+2)V1(s)|s=−2

Substitute 20(2+s)(1+s) for V1(s) as follows.

B=(s+2)[20(2+s)(1+s)]s=−2=[201+s]s=−2=[20−1]=−20

Substitute 20 for A and −20 for B in equation (5) as follows.

V1(s)=201+s−202+s

Take partial fraction for V2(s).

V2(s)=C1+s+D4+s (6)

Where,

C=(s+1)V2(s)|s=−1

Substitute 12(4+s)(1+s) for V2(s) as follows.

C=(s+1)[12(4+s)(1+s)]s=−1=[124+s]s=−1=[123]=4

Similarly,

D=(s+4)V2(s)|s=−4

Substitute 12(4+s)(1+s) for V2(s) as follows.

D=(s+4)[12(4+s)(1+s)]s=−4=[121+s]s=−4=12−3=−4

Substitute 4 for C and −4 for D in equation (6) as follows.

V2(s)=41+s−44+s

Substitute 201+s−202+s for V1(s) and 41+s−44+s for V2(s) in equation (4) as follows.

Vo(s)=[201+s−202+s]−[41+s−44+s]=201+s−202+s−41+s+44+s=161+s−202+s+44+s

Substitute jω for s as follows.

Vo(ω)=16jω+1−20jω+2+4jω+4

Apply inverse Fourier transform on both sides of equation.

F−1[Vo(ω)]=F−1[16jω+1−20jω+2+4jω+4]vo(t)=F−1[16jω+1]−F−1[20jω+2]+F−1[4jω+4]vo(t)=16e−tu(t)−20e−2tu(t)+4e−4tu(t)vo(t)=(16e−t−20e−2t+4e−4t)u(t)

Conclusion:

Thus, the output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Answer 6

Chapter 18, Problem 59P

To determine

Find the output voltage when the input voltage vi(t)=4e−tu(t) V

Expert Solution & Answer

Answer to Problem 59P

The output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Explanation of Solution

Given data:

vi(t)=2δ(t) V (1)

vo(t)=10e−2t−6e−4t V (2)

Formula used:

Consider the general expression for transfer function.

H(ω)=Vo(ω)Vi(ω) (3)

Here,

Vo(ω) is the output voltage.

Vi(ω) is the input voltage.

Calculation:

Apply Fourier transform on both sides of equation (1) as follows.

F[vi(t)]=F[2δ(t)]Vi(ω)=2

Apply Fourier transform on both sides of equation (2) as follows.

F[vo(t)]=F[10e−2t−6e−4t]Vo(ω)=F[10e−2t]−F[6e−4t]Vo(ω)=102+jω−64+jω

Substitute 2 for Vi(ω) and 102+jω−64+jω for Vo(ω) in equation (3) as follows.

H(ω)=(102+jω−64+jω)2=52+jω−34+jω

Consider vi(t)=4e−tu(t) V.

Apply Fourier transform on both sides of equation as follows.

F[vi(t)]=F[4e−tu(t)]Vi(ω)=41+jω

Rearrange equation (3) as follows.

Vo(ω)=H(ω)Vi(ω)

Substitute (52+jω−34+jω) for H(ω) and 41+jω for Vi(ω) as follows.

Vo(ω)=(52+jω−34+jω)(41+jω)=20(2+jω)(1+jω)−12(4+jω)(1+jω)

Consider s=jω to reduce complex algebra.

Substitute s for jω as follows.

Vo(s)=20(2+s)(1+s)−12(4+s)(1+s)

Consider Vo(s)=V1(s)−V2(s) (4)

Here,

V1(s)=20(2+s)(1+s)V2(s)=12(4+s)(1+s)

Take partial fraction for V1(s).

V1(s)=A1+s+B2+s (5)

Where,

A=(s+1)V1(s)|s=−1

Substitute 20(2+s)(1+s) for V1(s) as follows.

A=(s+1)[20(2+s)(1+s)]s=−1=[20(2+s)]s=−1=[201]=20

Similarly,

B=(s+2)V1(s)|s=−2

Substitute 20(2+s)(1+s) for V1(s) as follows.

B=(s+2)[20(2+s)(1+s)]s=−2=[201+s]s=−2=[20−1]=−20

Substitute 20 for A and −20 for B in equation (5) as follows.

V1(s)=201+s−202+s

Take partial fraction for V2(s).

V2(s)=C1+s+D4+s (6)

Where,

C=(s+1)V2(s)|s=−1

Substitute 12(4+s)(1+s) for V2(s) as follows.

C=(s+1)[12(4+s)(1+s)]s=−1=[124+s]s=−1=[123]=4

Similarly,

D=(s+4)V2(s)|s=−4

Substitute 12(4+s)(1+s) for V2(s) as follows.

D=(s+4)[12(4+s)(1+s)]s=−4=[121+s]s=−4=12−3=−4

Substitute 4 for C and −4 for D in equation (6) as follows.

V2(s)=41+s−44+s

Substitute 201+s−202+s for V1(s) and 41+s−44+s for V2(s) in equation (4) as follows.

Vo(s)=[201+s−202+s]−[41+s−44+s]=201+s−202+s−41+s+44+s=161+s−202+s+44+s

Substitute jω for s as follows.

Vo(ω)=16jω+1−20jω+2+4jω+4

Apply inverse Fourier transform on both sides of equation.

F−1[Vo(ω)]=F−1[16jω+1−20jω+2+4jω+4]vo(t)=F−1[16jω+1]−F−1[20jω+2]+F−1[4jω+4]vo(t)=16e−tu(t)−20e−2tu(t)+4e−4tu(t)vo(t)=(16e−t−20e−2t+4e−4t)u(t)

Conclusion:

Thus, the output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Answer 7

Chapter 18, Problem 59P

To determine

Find the output voltage when the input voltage vi(t)=4e−tu(t) V

Answer 8

Expert Solution & Answer

Answer to Problem 59P

The output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given data:

vi(t)=2δ(t) V (1)

vo(t)=10e−2t−6e−4t V (2)

Formula used:

Consider the general expression for transfer function.

H(ω)=Vo(ω)Vi(ω) (3)

Here,

Vo(ω) is the output voltage.

Vi(ω) is the input voltage.

Calculation:

Apply Fourier transform on both sides of equation (1) as follows.

F[vi(t)]=F[2δ(t)]Vi(ω)=2

Apply Fourier transform on both sides of equation (2) as follows.

F[vo(t)]=F[10e−2t−6e−4t]Vo(ω)=F[10e−2t]−F[6e−4t]Vo(ω)=102+jω−64+jω

Substitute 2 for Vi(ω) and 102+jω−64+jω for Vo(ω) in equation (3) as follows.

H(ω)=(102+jω−64+jω)2=52+jω−34+jω

Consider vi(t)=4e−tu(t) V.

Apply Fourier transform on both sides of equation as follows.

F[vi(t)]=F[4e−tu(t)]Vi(ω)=41+jω

Rearrange equation (3) as follows.

Vo(ω)=H(ω)Vi(ω)

Substitute (52+jω−34+jω) for H(ω) and 41+jω for Vi(ω) as follows.

Vo(ω)=(52+jω−34+jω)(41+jω)=20(2+jω)(1+jω)−12(4+jω)(1+jω)

Consider s=jω to reduce complex algebra.

Substitute s for jω as follows.

Vo(s)=20(2+s)(1+s)−12(4+s)(1+s)

Consider Vo(s)=V1(s)−V2(s) (4)

Here,

V1(s)=20(2+s)(1+s)V2(s)=12(4+s)(1+s)

Take partial fraction for V1(s).

V1(s)=A1+s+B2+s (5)

Where,

A=(s+1)V1(s)|s=−1

Substitute 20(2+s)(1+s) for V1(s) as follows.

A=(s+1)[20(2+s)(1+s)]s=−1=[20(2+s)]s=−1=[201]=20

Similarly,

B=(s+2)V1(s)|s=−2

Substitute 20(2+s)(1+s) for V1(s) as follows.

B=(s+2)[20(2+s)(1+s)]s=−2=[201+s]s=−2=[20−1]=−20

Substitute 20 for A and −20 for B in equation (5) as follows.

V1(s)=201+s−202+s

Take partial fraction for V2(s).

V2(s)=C1+s+D4+s (6)

Where,

C=(s+1)V2(s)|s=−1

Substitute 12(4+s)(1+s) for V2(s) as follows.

C=(s+1)[12(4+s)(1+s)]s=−1=[124+s]s=−1=[123]=4

Similarly,

D=(s+4)V2(s)|s=−4

Substitute 12(4+s)(1+s) for V2(s) as follows.

D=(s+4)[12(4+s)(1+s)]s=−4=[121+s]s=−4=12−3=−4

Substitute 4 for C and −4 for D in equation (6) as follows.

V2(s)=41+s−44+s

Substitute 201+s−202+s for V1(s) and 41+s−44+s for V2(s) in equation (4) as follows.

Vo(s)=[201+s−202+s]−[41+s−44+s]=201+s−202+s−41+s+44+s=161+s−202+s+44+s

Substitute jω for s as follows.

Vo(ω)=16jω+1−20jω+2+4jω+4

Apply inverse Fourier transform on both sides of equation.

F−1[Vo(ω)]=F−1[16jω+1−20jω+2+4jω+4]vo(t)=F−1[16jω+1]−F−1[20jω+2]+F−1[4jω+4]vo(t)=16e−tu(t)−20e−2tu(t)+4e−4tu(t)vo(t)=(16e−t−20e−2t+4e−4t)u(t)

Conclusion:

Thus, the output voltage when the input voltage vi(t)=4e−tu(t) V is (16e−t−20e−2t+4e−4t)u(t) V_.

Answer 12

Ch. 18.2 - Prob. 1PP Ch. 18.2 - Prob. 2PP Ch. 18.2 - Prob. 3PP Ch. 18.3 - Prob. 5PP Ch. 18.3 - Prob. 6PP Ch. 18.4 - Prob. 7PP Ch. 18.4 - Prob. 8PP Ch. 18.5 - (a) Calculate the total energy absorbed by a 1-...Ch. 18.5 - Prob. 10PP Ch. 18.8 - If a 2-MHz carrier is modulated by a 4-kHz...

Find the output voltage when the input voltage v i ( t ) = 4 e − t u ( t ) V

Videos

Find the output voltage when the input voltage vi(t)=4e−tu(t) V

Answer to Problem 59P

Explanation of Solution

Want to see more full solutions like this?

Chapter 18 Solutions