Find the time-varying function y ( t ) for the given differential equation using Laplace transform method.

Question

Want to see more full solutions like this?

Answer 1

Question

Chapter 15, Problem 55P

To determine

Find the time-varying function y(t) for the given differential equation using Laplace transform method.

Expert Solution & Answer

Answer to Problem 55P

The time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Explanation of Solution

Given data:

The differential equation is,

d3ydt3+6d2ydt2+8dydt=e−tcos2t (1)

The initial conditions are zero. That is,

y(0)=y'(0)=y''(0)=0

Formula used:

Write the general expression for the Laplace transform.

F(s)=L[f(t)] (2)

Write the general expression for the inverse Laplace transform.

f(t)=L−1[F(s)] (3)

Write the general expressions to find the Laplace transform function.

L[dfdt]=sF(s)−f(0−) (4)

L[d2fdt2]=s2F(s)−sf(0−)−f'(0−) (5)

L[d3fdt3]=s3F(s)−s2f(0−)−sf'(0−)−f''(0−) (6)

L[e−atcosωt]=s+a(s+a)2+ω2 (7)

Here,

s is a complex variable,

ω is the angular frequency, and

s+a is the frequency shift or frequency translation.

Write the general expressions to find the inverse Laplace transform function.

L−1[1s+a]=e−atu(t) (8)

L−1[s+a(s+a)2+ω2]=e−atcosωt u(t) (9)

L−1[ω(s+a)2+ω2]=e−atsinωt u(t) (10)

L−1[1s]=u(t) (11)

Calculation:

Apply Laplace transform function given in equation (2), (4), (5), (6) and (7) to equation (1).

([s3Y(s)−s2y(0−)−sy'(0−)−y''(0−)]+6[s2Y(s)−sy(0−)−y'(0−)]+8[sY(s)−y(0−)])=s+1(s+1)2+22

([s3Y(s)−s2y(0)−sy'(0)−y''(0)]+6[s2Y(s)−sy(0)−y'(0)]+8[sY(s)−y(0)])=s+1(s+1)2+22 {∵y(0−)=y(0), y'(0−)=y'(0)} (12)

Substitute 0 for y(0), 0 for y'(0) and 0 for y''(0) in equation (12).

[s3Y(s)−s2(0)−s(0)−0]+6[s2Y(s)−s(0)−0]+8[sY(s)−0]=s+1(s+1)2+22s3Y(s)+6s2Y(s)+8sY(s)=s+1s2+2s+1+22 {∵(a+b)2=a2+2ab+b2}(s3+6s2+8s)Y(s)=s+1s2+2s+1+4

(s3+6s2+8s)Y(s)=s+1s2+2s+5 (13)

Rearrange the equation (13) to find Y(s).

Y(s)=s+1(s3+6s2+8s)(s2+2s+5)=s+1s(s2+6s+8)(s2+2s+5)=s+1s(s2+2s+4s+8)(s2+2s+5)=s+1s(s(s+2)+4(s+2))(s2+2s+5)

Reduce the equation as follows,

Y(s)=s+1s(s+2)(s+4)(s2+2s+5) (14)

Expand Y(s) using partial fraction.

Y(s)=s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5 (15)

Here,

A, B, C, D and E are the constants.

Now, to find the constants by using residue and algebraic method.

Constant A:

A=sY(s)|s=0 (16)

Substitute equation (14) in equation (16) to find the constant A.

A=s×s+1s(s+2)(s+4)(s2+2s+5)|s=0=s+1(s+2)(s+4)(s2+2s+5)|s=0=0+1(0+2)(0+4)((0)2+2(0)+5)=140

Constant B:

B=(s+2)Y(s)|s+2=0 (17)

Substitute equation (14) in equation (17) to find the constant B.

B=(s+2)×s+1s(s+2)(s+4)(s2+2s+5)|s=−2=s+1s(s+4)(s2+2s+5)|s=−2=−2+1(−2)(−2+4)((−2)2+2(−2)+5)=120

Constant C:

C=(s+4)Y(s)|s+4=0 (18)

Substitute equation (14) in equation (18) to find the constant C.

C=(s+4)×s+1s(s+2)(s+4)(s2+2s+5)|s=−4=s+1s(s+2)(s2+2s+5)|s=−4=−4+1(−4)(−4+2)((−4)2+2(−4)+5)=−3104

Consider the partial fraction,

s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5s+1s(s+2)(s+4)(s2+2s+5)=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s(s+2)(s+4)(s2+2s+5)s+1=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s+1=(A(s2+2s+4s+8)(s2+2s+5)+B(s2+4s)(s2+2s+5)+C(s2+2s)(s2+2s+5)+(Ds+E)s(s2+2s+4s+8))

Reduce the equation as follows,

s+1=(A(s2+6s+8)(s2+2s+5)+B(s4+2s3+5s2+4s3+8s2+20s)+C(s4+2s3+5s2+2s3+4s2+10s)+(Ds+E)(s3+6s2+8s))s+1=(A(s4+2s3+5s2+6s3+12s2+30s+8s2+16s+40)+B(s4+6s3+13s2+20s)+C(s4+4s3+9s2+10s)+D(s4+6s3+8s2)+E(s3+6s2+8s))s+1=(As4+8As3+25As2+46As+40A+Bs4+6Bs3+13Bs2+20Bs+Cs4+4Cs3+9Cs2+10Cs+Ds4+6Ds3+8Ds2+Es3+6Es2+8Es)

s+1=((A+B+C+D)s4+(8A+6B+4C+6D+E)s3+(25A+13B+9C+8D+6E)s2+(46A+20B+10C+8E)s+40A) (19)

Equate the coefficients of s4 in equation (19).

0=A+B+C+D (20)

Substitute 140 for A, 120 for B, and −3104 for C in equation (20) to find the constant D.

0=140+120−3104+DD=−140−120+3104D=−365

Equate the coefficients of s3 in equation (19).

0=8A+6B+4C+6D+E (21)

Substitute 140 for A, 120 for B, −3104 for C, and −365 for D in equation (21) to find the constant E.

0=8(140)+6(120)+4(−3104)+6(−365)+EE=−840−620+12104+1865E=−765

Substitute 140 for A, 120 for B, −3104 for C, −365 for D, and −765 for E in equation (15) to find Y(s).

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)s+(−765)s2+2s+5=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+7)s2+2s+1+4=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3+4)(s+1)2+4 {∵(a+b)2=a2+2ab+b2}

Reduce the equation as follows,

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3)+(−165)4(s+1)2+4=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+4+(−165)4(s+1)2+4

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22 (22)

Apply inverse Laplace transform given in equation (3) to equation (22). Therefore,

y(t)=L−1[Y(s)]=L−1[(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22]={L−1[(140)s]+L−1[(120)s+2]+L−1[(−3104)s+4]+L−1[(−365)(s+1)(s+1)2+22]+L−1[(−265)2(s+1)2+22]}

y(t)={140L−1[1s]+120L−1[1s+2]−3104L−1[1s+4]−365L−1[(s+1)(s+1)2+22]−265L−1[2(s+1)2+22]} (23)

Apply inverse Laplace transform function given in equation (8), (9), (10) and (11) to equation (23).

y(t)=140u(t)+120e−2t u(t)−3104e−4t u(t)−365e−tcos(2t) u(t)−265e−tsin(2t) u(t)=(140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t)

Conclusion:

Thus, the time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

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

P7.2 The capacitors in the circuit shown below have no energy stored in them and then switch "A" closes at time t=0. Switch "B" closes 2.5 milliseconds later. Find v(t) across the 6 μF capacitor for t≥ 0. 500 Ω B 4 µF 20 V 6 µF 7 Σ2 ΚΩ 25 mA + · με

Q1: If x[n] is a discrete signal and represented by the following equation, what is the value of x[0] and X[-2] Q2: {x[n]}={-0.2,2.2,1.1,0.2,-3.7,2.9,...} a- Assuming that a 5-bit ADC channel accepts analog input ranging from 0 to 4 volts, determine the following: 1- number of quantization levels; 2-step size of the quantizer or resolution; 3- quantization level when the analog voltage is 1.28 volts. 4- binary code produced by the ADC. 5- quantization error. b- Determine whether the linear system is time invariant or not? 1 1 y(n) = x(n) Q3: Evaluate the digital convolution of the following signals using Graphical method. Find: y(0) to y(3) Q4: 2, k = 0,1,2 2, k = 0 h(k) 0 1, k = 3,4 and x(k) elsewhere = 1, k = 1,2 0 elsewhere The temperature (in Kelvin) of an electronic component can be modelled using the following approximation: T(t) [293+15e-Ju(t) A digital thermometer is used to periodically record the component's temperature, taking a sample every 5 seconds. 1- Represent the…

I need solution by hand clearly

Answer 2

Question

Chapter 15, Problem 55P

To determine

Find the time-varying function y(t) for the given differential equation using Laplace transform method.

Expert Solution & Answer

Answer to Problem 55P

The time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Explanation of Solution

Given data:

The differential equation is,

d3ydt3+6d2ydt2+8dydt=e−tcos2t (1)

The initial conditions are zero. That is,

y(0)=y'(0)=y''(0)=0

Formula used:

Write the general expression for the Laplace transform.

F(s)=L[f(t)] (2)

Write the general expression for the inverse Laplace transform.

f(t)=L−1[F(s)] (3)

Write the general expressions to find the Laplace transform function.

L[dfdt]=sF(s)−f(0−) (4)

L[d2fdt2]=s2F(s)−sf(0−)−f'(0−) (5)

L[d3fdt3]=s3F(s)−s2f(0−)−sf'(0−)−f''(0−) (6)

L[e−atcosωt]=s+a(s+a)2+ω2 (7)

Here,

s is a complex variable,

ω is the angular frequency, and

s+a is the frequency shift or frequency translation.

Write the general expressions to find the inverse Laplace transform function.

L−1[1s+a]=e−atu(t) (8)

L−1[s+a(s+a)2+ω2]=e−atcosωt u(t) (9)

L−1[ω(s+a)2+ω2]=e−atsinωt u(t) (10)

L−1[1s]=u(t) (11)

Calculation:

Apply Laplace transform function given in equation (2), (4), (5), (6) and (7) to equation (1).

([s3Y(s)−s2y(0−)−sy'(0−)−y''(0−)]+6[s2Y(s)−sy(0−)−y'(0−)]+8[sY(s)−y(0−)])=s+1(s+1)2+22

([s3Y(s)−s2y(0)−sy'(0)−y''(0)]+6[s2Y(s)−sy(0)−y'(0)]+8[sY(s)−y(0)])=s+1(s+1)2+22 {∵y(0−)=y(0), y'(0−)=y'(0)} (12)

Substitute 0 for y(0), 0 for y'(0) and 0 for y''(0) in equation (12).

[s3Y(s)−s2(0)−s(0)−0]+6[s2Y(s)−s(0)−0]+8[sY(s)−0]=s+1(s+1)2+22s3Y(s)+6s2Y(s)+8sY(s)=s+1s2+2s+1+22 {∵(a+b)2=a2+2ab+b2}(s3+6s2+8s)Y(s)=s+1s2+2s+1+4

(s3+6s2+8s)Y(s)=s+1s2+2s+5 (13)

Rearrange the equation (13) to find Y(s).

Y(s)=s+1(s3+6s2+8s)(s2+2s+5)=s+1s(s2+6s+8)(s2+2s+5)=s+1s(s2+2s+4s+8)(s2+2s+5)=s+1s(s(s+2)+4(s+2))(s2+2s+5)

Reduce the equation as follows,

Y(s)=s+1s(s+2)(s+4)(s2+2s+5) (14)

Expand Y(s) using partial fraction.

Y(s)=s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5 (15)

Here,

A, B, C, D and E are the constants.

Now, to find the constants by using residue and algebraic method.

Constant A:

A=sY(s)|s=0 (16)

Substitute equation (14) in equation (16) to find the constant A.

A=s×s+1s(s+2)(s+4)(s2+2s+5)|s=0=s+1(s+2)(s+4)(s2+2s+5)|s=0=0+1(0+2)(0+4)((0)2+2(0)+5)=140

Constant B:

B=(s+2)Y(s)|s+2=0 (17)

Substitute equation (14) in equation (17) to find the constant B.

B=(s+2)×s+1s(s+2)(s+4)(s2+2s+5)|s=−2=s+1s(s+4)(s2+2s+5)|s=−2=−2+1(−2)(−2+4)((−2)2+2(−2)+5)=120

Constant C:

C=(s+4)Y(s)|s+4=0 (18)

Substitute equation (14) in equation (18) to find the constant C.

C=(s+4)×s+1s(s+2)(s+4)(s2+2s+5)|s=−4=s+1s(s+2)(s2+2s+5)|s=−4=−4+1(−4)(−4+2)((−4)2+2(−4)+5)=−3104

Consider the partial fraction,

s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5s+1s(s+2)(s+4)(s2+2s+5)=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s(s+2)(s+4)(s2+2s+5)s+1=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s+1=(A(s2+2s+4s+8)(s2+2s+5)+B(s2+4s)(s2+2s+5)+C(s2+2s)(s2+2s+5)+(Ds+E)s(s2+2s+4s+8))

Reduce the equation as follows,

s+1=(A(s2+6s+8)(s2+2s+5)+B(s4+2s3+5s2+4s3+8s2+20s)+C(s4+2s3+5s2+2s3+4s2+10s)+(Ds+E)(s3+6s2+8s))s+1=(A(s4+2s3+5s2+6s3+12s2+30s+8s2+16s+40)+B(s4+6s3+13s2+20s)+C(s4+4s3+9s2+10s)+D(s4+6s3+8s2)+E(s3+6s2+8s))s+1=(As4+8As3+25As2+46As+40A+Bs4+6Bs3+13Bs2+20Bs+Cs4+4Cs3+9Cs2+10Cs+Ds4+6Ds3+8Ds2+Es3+6Es2+8Es)

s+1=((A+B+C+D)s4+(8A+6B+4C+6D+E)s3+(25A+13B+9C+8D+6E)s2+(46A+20B+10C+8E)s+40A) (19)

Equate the coefficients of s4 in equation (19).

0=A+B+C+D (20)

Substitute 140 for A, 120 for B, and −3104 for C in equation (20) to find the constant D.

0=140+120−3104+DD=−140−120+3104D=−365

Equate the coefficients of s3 in equation (19).

0=8A+6B+4C+6D+E (21)

Substitute 140 for A, 120 for B, −3104 for C, and −365 for D in equation (21) to find the constant E.

0=8(140)+6(120)+4(−3104)+6(−365)+EE=−840−620+12104+1865E=−765

Substitute 140 for A, 120 for B, −3104 for C, −365 for D, and −765 for E in equation (15) to find Y(s).

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)s+(−765)s2+2s+5=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+7)s2+2s+1+4=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3+4)(s+1)2+4 {∵(a+b)2=a2+2ab+b2}

Reduce the equation as follows,

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3)+(−165)4(s+1)2+4=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+4+(−165)4(s+1)2+4

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22 (22)

Apply inverse Laplace transform given in equation (3) to equation (22). Therefore,

y(t)=L−1[Y(s)]=L−1[(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22]={L−1[(140)s]+L−1[(120)s+2]+L−1[(−3104)s+4]+L−1[(−365)(s+1)(s+1)2+22]+L−1[(−265)2(s+1)2+22]}

y(t)={140L−1[1s]+120L−1[1s+2]−3104L−1[1s+4]−365L−1[(s+1)(s+1)2+22]−265L−1[2(s+1)2+22]} (23)

Apply inverse Laplace transform function given in equation (8), (9), (10) and (11) to equation (23).

y(t)=140u(t)+120e−2t u(t)−3104e−4t u(t)−365e−tcos(2t) u(t)−265e−tsin(2t) u(t)=(140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t)

Conclusion:

Thus, the time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

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 15, Problem 55P

To determine

Find the time-varying function y(t) for the given differential equation using Laplace transform method.

Expert Solution & Answer

Answer to Problem 55P

The time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Explanation of Solution

Given data:

The differential equation is,

d3ydt3+6d2ydt2+8dydt=e−tcos2t (1)

The initial conditions are zero. That is,

y(0)=y'(0)=y''(0)=0

Formula used:

Write the general expression for the Laplace transform.

F(s)=L[f(t)] (2)

Write the general expression for the inverse Laplace transform.

f(t)=L−1[F(s)] (3)

Write the general expressions to find the Laplace transform function.

L[dfdt]=sF(s)−f(0−) (4)

L[d2fdt2]=s2F(s)−sf(0−)−f'(0−) (5)

L[d3fdt3]=s3F(s)−s2f(0−)−sf'(0−)−f''(0−) (6)

L[e−atcosωt]=s+a(s+a)2+ω2 (7)

Here,

s is a complex variable,

ω is the angular frequency, and

s+a is the frequency shift or frequency translation.

Write the general expressions to find the inverse Laplace transform function.

L−1[1s+a]=e−atu(t) (8)

L−1[s+a(s+a)2+ω2]=e−atcosωt u(t) (9)

L−1[ω(s+a)2+ω2]=e−atsinωt u(t) (10)

L−1[1s]=u(t) (11)

Calculation:

Apply Laplace transform function given in equation (2), (4), (5), (6) and (7) to equation (1).

([s3Y(s)−s2y(0−)−sy'(0−)−y''(0−)]+6[s2Y(s)−sy(0−)−y'(0−)]+8[sY(s)−y(0−)])=s+1(s+1)2+22

([s3Y(s)−s2y(0)−sy'(0)−y''(0)]+6[s2Y(s)−sy(0)−y'(0)]+8[sY(s)−y(0)])=s+1(s+1)2+22 {∵y(0−)=y(0), y'(0−)=y'(0)} (12)

Substitute 0 for y(0), 0 for y'(0) and 0 for y''(0) in equation (12).

[s3Y(s)−s2(0)−s(0)−0]+6[s2Y(s)−s(0)−0]+8[sY(s)−0]=s+1(s+1)2+22s3Y(s)+6s2Y(s)+8sY(s)=s+1s2+2s+1+22 {∵(a+b)2=a2+2ab+b2}(s3+6s2+8s)Y(s)=s+1s2+2s+1+4

(s3+6s2+8s)Y(s)=s+1s2+2s+5 (13)

Rearrange the equation (13) to find Y(s).

Y(s)=s+1(s3+6s2+8s)(s2+2s+5)=s+1s(s2+6s+8)(s2+2s+5)=s+1s(s2+2s+4s+8)(s2+2s+5)=s+1s(s(s+2)+4(s+2))(s2+2s+5)

Reduce the equation as follows,

Y(s)=s+1s(s+2)(s+4)(s2+2s+5) (14)

Expand Y(s) using partial fraction.

Y(s)=s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5 (15)

Here,

A, B, C, D and E are the constants.

Now, to find the constants by using residue and algebraic method.

Constant A:

A=sY(s)|s=0 (16)

Substitute equation (14) in equation (16) to find the constant A.

A=s×s+1s(s+2)(s+4)(s2+2s+5)|s=0=s+1(s+2)(s+4)(s2+2s+5)|s=0=0+1(0+2)(0+4)((0)2+2(0)+5)=140

Constant B:

B=(s+2)Y(s)|s+2=0 (17)

Substitute equation (14) in equation (17) to find the constant B.

B=(s+2)×s+1s(s+2)(s+4)(s2+2s+5)|s=−2=s+1s(s+4)(s2+2s+5)|s=−2=−2+1(−2)(−2+4)((−2)2+2(−2)+5)=120

Constant C:

C=(s+4)Y(s)|s+4=0 (18)

Substitute equation (14) in equation (18) to find the constant C.

C=(s+4)×s+1s(s+2)(s+4)(s2+2s+5)|s=−4=s+1s(s+2)(s2+2s+5)|s=−4=−4+1(−4)(−4+2)((−4)2+2(−4)+5)=−3104

Consider the partial fraction,

s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5s+1s(s+2)(s+4)(s2+2s+5)=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s(s+2)(s+4)(s2+2s+5)s+1=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s+1=(A(s2+2s+4s+8)(s2+2s+5)+B(s2+4s)(s2+2s+5)+C(s2+2s)(s2+2s+5)+(Ds+E)s(s2+2s+4s+8))

Reduce the equation as follows,

s+1=(A(s2+6s+8)(s2+2s+5)+B(s4+2s3+5s2+4s3+8s2+20s)+C(s4+2s3+5s2+2s3+4s2+10s)+(Ds+E)(s3+6s2+8s))s+1=(A(s4+2s3+5s2+6s3+12s2+30s+8s2+16s+40)+B(s4+6s3+13s2+20s)+C(s4+4s3+9s2+10s)+D(s4+6s3+8s2)+E(s3+6s2+8s))s+1=(As4+8As3+25As2+46As+40A+Bs4+6Bs3+13Bs2+20Bs+Cs4+4Cs3+9Cs2+10Cs+Ds4+6Ds3+8Ds2+Es3+6Es2+8Es)

s+1=((A+B+C+D)s4+(8A+6B+4C+6D+E)s3+(25A+13B+9C+8D+6E)s2+(46A+20B+10C+8E)s+40A) (19)

Equate the coefficients of s4 in equation (19).

0=A+B+C+D (20)

Substitute 140 for A, 120 for B, and −3104 for C in equation (20) to find the constant D.

0=140+120−3104+DD=−140−120+3104D=−365

Equate the coefficients of s3 in equation (19).

0=8A+6B+4C+6D+E (21)

Substitute 140 for A, 120 for B, −3104 for C, and −365 for D in equation (21) to find the constant E.

0=8(140)+6(120)+4(−3104)+6(−365)+EE=−840−620+12104+1865E=−765

Substitute 140 for A, 120 for B, −3104 for C, −365 for D, and −765 for E in equation (15) to find Y(s).

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)s+(−765)s2+2s+5=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+7)s2+2s+1+4=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3+4)(s+1)2+4 {∵(a+b)2=a2+2ab+b2}

Reduce the equation as follows,

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3)+(−165)4(s+1)2+4=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+4+(−165)4(s+1)2+4

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22 (22)

Apply inverse Laplace transform given in equation (3) to equation (22). Therefore,

y(t)=L−1[Y(s)]=L−1[(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22]={L−1[(140)s]+L−1[(120)s+2]+L−1[(−3104)s+4]+L−1[(−365)(s+1)(s+1)2+22]+L−1[(−265)2(s+1)2+22]}

y(t)={140L−1[1s]+120L−1[1s+2]−3104L−1[1s+4]−365L−1[(s+1)(s+1)2+22]−265L−1[2(s+1)2+22]} (23)

Apply inverse Laplace transform function given in equation (8), (9), (10) and (11) to equation (23).

y(t)=140u(t)+120e−2t u(t)−3104e−4t u(t)−365e−tcos(2t) u(t)−265e−tsin(2t) u(t)=(140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t)

Conclusion:

Thus, the time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

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 15, Problem 55P

To determine

Find the time-varying function y(t) for the given differential equation using Laplace transform method.

Expert Solution & Answer

Answer to Problem 55P

The time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Explanation of Solution

Given data:

The differential equation is,

d3ydt3+6d2ydt2+8dydt=e−tcos2t (1)

The initial conditions are zero. That is,

y(0)=y'(0)=y''(0)=0

Formula used:

Write the general expression for the Laplace transform.

F(s)=L[f(t)] (2)

Write the general expression for the inverse Laplace transform.

f(t)=L−1[F(s)] (3)

Write the general expressions to find the Laplace transform function.

L[dfdt]=sF(s)−f(0−) (4)

L[d2fdt2]=s2F(s)−sf(0−)−f'(0−) (5)

L[d3fdt3]=s3F(s)−s2f(0−)−sf'(0−)−f''(0−) (6)

L[e−atcosωt]=s+a(s+a)2+ω2 (7)

Here,

s is a complex variable,

ω is the angular frequency, and

s+a is the frequency shift or frequency translation.

Write the general expressions to find the inverse Laplace transform function.

L−1[1s+a]=e−atu(t) (8)

L−1[s+a(s+a)2+ω2]=e−atcosωt u(t) (9)

L−1[ω(s+a)2+ω2]=e−atsinωt u(t) (10)

L−1[1s]=u(t) (11)

Calculation:

Apply Laplace transform function given in equation (2), (4), (5), (6) and (7) to equation (1).

([s3Y(s)−s2y(0−)−sy'(0−)−y''(0−)]+6[s2Y(s)−sy(0−)−y'(0−)]+8[sY(s)−y(0−)])=s+1(s+1)2+22

([s3Y(s)−s2y(0)−sy'(0)−y''(0)]+6[s2Y(s)−sy(0)−y'(0)]+8[sY(s)−y(0)])=s+1(s+1)2+22 {∵y(0−)=y(0), y'(0−)=y'(0)} (12)

Substitute 0 for y(0), 0 for y'(0) and 0 for y''(0) in equation (12).

[s3Y(s)−s2(0)−s(0)−0]+6[s2Y(s)−s(0)−0]+8[sY(s)−0]=s+1(s+1)2+22s3Y(s)+6s2Y(s)+8sY(s)=s+1s2+2s+1+22 {∵(a+b)2=a2+2ab+b2}(s3+6s2+8s)Y(s)=s+1s2+2s+1+4

(s3+6s2+8s)Y(s)=s+1s2+2s+5 (13)

Rearrange the equation (13) to find Y(s).

Y(s)=s+1(s3+6s2+8s)(s2+2s+5)=s+1s(s2+6s+8)(s2+2s+5)=s+1s(s2+2s+4s+8)(s2+2s+5)=s+1s(s(s+2)+4(s+2))(s2+2s+5)

Reduce the equation as follows,

Y(s)=s+1s(s+2)(s+4)(s2+2s+5) (14)

Expand Y(s) using partial fraction.

Y(s)=s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5 (15)

Here,

A, B, C, D and E are the constants.

Now, to find the constants by using residue and algebraic method.

Constant A:

A=sY(s)|s=0 (16)

Substitute equation (14) in equation (16) to find the constant A.

A=s×s+1s(s+2)(s+4)(s2+2s+5)|s=0=s+1(s+2)(s+4)(s2+2s+5)|s=0=0+1(0+2)(0+4)((0)2+2(0)+5)=140

Constant B:

B=(s+2)Y(s)|s+2=0 (17)

Substitute equation (14) in equation (17) to find the constant B.

B=(s+2)×s+1s(s+2)(s+4)(s2+2s+5)|s=−2=s+1s(s+4)(s2+2s+5)|s=−2=−2+1(−2)(−2+4)((−2)2+2(−2)+5)=120

Constant C:

C=(s+4)Y(s)|s+4=0 (18)

Substitute equation (14) in equation (18) to find the constant C.

C=(s+4)×s+1s(s+2)(s+4)(s2+2s+5)|s=−4=s+1s(s+2)(s2+2s+5)|s=−4=−4+1(−4)(−4+2)((−4)2+2(−4)+5)=−3104

Consider the partial fraction,

s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5s+1s(s+2)(s+4)(s2+2s+5)=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s(s+2)(s+4)(s2+2s+5)s+1=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s+1=(A(s2+2s+4s+8)(s2+2s+5)+B(s2+4s)(s2+2s+5)+C(s2+2s)(s2+2s+5)+(Ds+E)s(s2+2s+4s+8))

Reduce the equation as follows,

s+1=(A(s2+6s+8)(s2+2s+5)+B(s4+2s3+5s2+4s3+8s2+20s)+C(s4+2s3+5s2+2s3+4s2+10s)+(Ds+E)(s3+6s2+8s))s+1=(A(s4+2s3+5s2+6s3+12s2+30s+8s2+16s+40)+B(s4+6s3+13s2+20s)+C(s4+4s3+9s2+10s)+D(s4+6s3+8s2)+E(s3+6s2+8s))s+1=(As4+8As3+25As2+46As+40A+Bs4+6Bs3+13Bs2+20Bs+Cs4+4Cs3+9Cs2+10Cs+Ds4+6Ds3+8Ds2+Es3+6Es2+8Es)

s+1=((A+B+C+D)s4+(8A+6B+4C+6D+E)s3+(25A+13B+9C+8D+6E)s2+(46A+20B+10C+8E)s+40A) (19)

Equate the coefficients of s4 in equation (19).

0=A+B+C+D (20)

Substitute 140 for A, 120 for B, and −3104 for C in equation (20) to find the constant D.

0=140+120−3104+DD=−140−120+3104D=−365

Equate the coefficients of s3 in equation (19).

0=8A+6B+4C+6D+E (21)

Substitute 140 for A, 120 for B, −3104 for C, and −365 for D in equation (21) to find the constant E.

0=8(140)+6(120)+4(−3104)+6(−365)+EE=−840−620+12104+1865E=−765

Substitute 140 for A, 120 for B, −3104 for C, −365 for D, and −765 for E in equation (15) to find Y(s).

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)s+(−765)s2+2s+5=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+7)s2+2s+1+4=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3+4)(s+1)2+4 {∵(a+b)2=a2+2ab+b2}

Reduce the equation as follows,

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3)+(−165)4(s+1)2+4=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+4+(−165)4(s+1)2+4

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22 (22)

Apply inverse Laplace transform given in equation (3) to equation (22). Therefore,

y(t)=L−1[Y(s)]=L−1[(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22]={L−1[(140)s]+L−1[(120)s+2]+L−1[(−3104)s+4]+L−1[(−365)(s+1)(s+1)2+22]+L−1[(−265)2(s+1)2+22]}

y(t)={140L−1[1s]+120L−1[1s+2]−3104L−1[1s+4]−365L−1[(s+1)(s+1)2+22]−265L−1[2(s+1)2+22]} (23)

Apply inverse Laplace transform function given in equation (8), (9), (10) and (11) to equation (23).

y(t)=140u(t)+120e−2t u(t)−3104e−4t u(t)−365e−tcos(2t) u(t)−265e−tsin(2t) u(t)=(140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t)

Conclusion:

Thus, the time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

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 15, Problem 55P

To determine

Find the time-varying function y(t) for the given differential equation using Laplace transform method.

Expert Solution & Answer

Answer to Problem 55P

The time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Explanation of Solution

Given data:

The differential equation is,

d3ydt3+6d2ydt2+8dydt=e−tcos2t (1)

The initial conditions are zero. That is,

y(0)=y'(0)=y''(0)=0

Formula used:

Write the general expression for the Laplace transform.

F(s)=L[f(t)] (2)

Write the general expression for the inverse Laplace transform.

f(t)=L−1[F(s)] (3)

Write the general expressions to find the Laplace transform function.

L[dfdt]=sF(s)−f(0−) (4)

L[d2fdt2]=s2F(s)−sf(0−)−f'(0−) (5)

L[d3fdt3]=s3F(s)−s2f(0−)−sf'(0−)−f''(0−) (6)

L[e−atcosωt]=s+a(s+a)2+ω2 (7)

Here,

s is a complex variable,

ω is the angular frequency, and

s+a is the frequency shift or frequency translation.

Write the general expressions to find the inverse Laplace transform function.

L−1[1s+a]=e−atu(t) (8)

L−1[s+a(s+a)2+ω2]=e−atcosωt u(t) (9)

L−1[ω(s+a)2+ω2]=e−atsinωt u(t) (10)

L−1[1s]=u(t) (11)

Calculation:

Apply Laplace transform function given in equation (2), (4), (5), (6) and (7) to equation (1).

([s3Y(s)−s2y(0−)−sy'(0−)−y''(0−)]+6[s2Y(s)−sy(0−)−y'(0−)]+8[sY(s)−y(0−)])=s+1(s+1)2+22

([s3Y(s)−s2y(0)−sy'(0)−y''(0)]+6[s2Y(s)−sy(0)−y'(0)]+8[sY(s)−y(0)])=s+1(s+1)2+22 {∵y(0−)=y(0), y'(0−)=y'(0)} (12)

Substitute 0 for y(0), 0 for y'(0) and 0 for y''(0) in equation (12).

[s3Y(s)−s2(0)−s(0)−0]+6[s2Y(s)−s(0)−0]+8[sY(s)−0]=s+1(s+1)2+22s3Y(s)+6s2Y(s)+8sY(s)=s+1s2+2s+1+22 {∵(a+b)2=a2+2ab+b2}(s3+6s2+8s)Y(s)=s+1s2+2s+1+4

(s3+6s2+8s)Y(s)=s+1s2+2s+5 (13)

Rearrange the equation (13) to find Y(s).

Y(s)=s+1(s3+6s2+8s)(s2+2s+5)=s+1s(s2+6s+8)(s2+2s+5)=s+1s(s2+2s+4s+8)(s2+2s+5)=s+1s(s(s+2)+4(s+2))(s2+2s+5)

Reduce the equation as follows,

Y(s)=s+1s(s+2)(s+4)(s2+2s+5) (14)

Expand Y(s) using partial fraction.

Y(s)=s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5 (15)

Here,

A, B, C, D and E are the constants.

Now, to find the constants by using residue and algebraic method.

Constant A:

A=sY(s)|s=0 (16)

Substitute equation (14) in equation (16) to find the constant A.

A=s×s+1s(s+2)(s+4)(s2+2s+5)|s=0=s+1(s+2)(s+4)(s2+2s+5)|s=0=0+1(0+2)(0+4)((0)2+2(0)+5)=140

Constant B:

B=(s+2)Y(s)|s+2=0 (17)

Substitute equation (14) in equation (17) to find the constant B.

B=(s+2)×s+1s(s+2)(s+4)(s2+2s+5)|s=−2=s+1s(s+4)(s2+2s+5)|s=−2=−2+1(−2)(−2+4)((−2)2+2(−2)+5)=120

Constant C:

C=(s+4)Y(s)|s+4=0 (18)

Substitute equation (14) in equation (18) to find the constant C.

C=(s+4)×s+1s(s+2)(s+4)(s2+2s+5)|s=−4=s+1s(s+2)(s2+2s+5)|s=−4=−4+1(−4)(−4+2)((−4)2+2(−4)+5)=−3104

Consider the partial fraction,

s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5s+1s(s+2)(s+4)(s2+2s+5)=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s(s+2)(s+4)(s2+2s+5)s+1=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s+1=(A(s2+2s+4s+8)(s2+2s+5)+B(s2+4s)(s2+2s+5)+C(s2+2s)(s2+2s+5)+(Ds+E)s(s2+2s+4s+8))

Reduce the equation as follows,

s+1=(A(s2+6s+8)(s2+2s+5)+B(s4+2s3+5s2+4s3+8s2+20s)+C(s4+2s3+5s2+2s3+4s2+10s)+(Ds+E)(s3+6s2+8s))s+1=(A(s4+2s3+5s2+6s3+12s2+30s+8s2+16s+40)+B(s4+6s3+13s2+20s)+C(s4+4s3+9s2+10s)+D(s4+6s3+8s2)+E(s3+6s2+8s))s+1=(As4+8As3+25As2+46As+40A+Bs4+6Bs3+13Bs2+20Bs+Cs4+4Cs3+9Cs2+10Cs+Ds4+6Ds3+8Ds2+Es3+6Es2+8Es)

s+1=((A+B+C+D)s4+(8A+6B+4C+6D+E)s3+(25A+13B+9C+8D+6E)s2+(46A+20B+10C+8E)s+40A) (19)

Equate the coefficients of s4 in equation (19).

0=A+B+C+D (20)

Substitute 140 for A, 120 for B, and −3104 for C in equation (20) to find the constant D.

0=140+120−3104+DD=−140−120+3104D=−365

Equate the coefficients of s3 in equation (19).

0=8A+6B+4C+6D+E (21)

Substitute 140 for A, 120 for B, −3104 for C, and −365 for D in equation (21) to find the constant E.

0=8(140)+6(120)+4(−3104)+6(−365)+EE=−840−620+12104+1865E=−765

Substitute 140 for A, 120 for B, −3104 for C, −365 for D, and −765 for E in equation (15) to find Y(s).

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)s+(−765)s2+2s+5=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+7)s2+2s+1+4=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3+4)(s+1)2+4 {∵(a+b)2=a2+2ab+b2}

Reduce the equation as follows,

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3)+(−165)4(s+1)2+4=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+4+(−165)4(s+1)2+4

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22 (22)

Apply inverse Laplace transform given in equation (3) to equation (22). Therefore,

y(t)=L−1[Y(s)]=L−1[(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22]={L−1[(140)s]+L−1[(120)s+2]+L−1[(−3104)s+4]+L−1[(−365)(s+1)(s+1)2+22]+L−1[(−265)2(s+1)2+22]}

y(t)={140L−1[1s]+120L−1[1s+2]−3104L−1[1s+4]−365L−1[(s+1)(s+1)2+22]−265L−1[2(s+1)2+22]} (23)

Apply inverse Laplace transform function given in equation (8), (9), (10) and (11) to equation (23).

y(t)=140u(t)+120e−2t u(t)−3104e−4t u(t)−365e−tcos(2t) u(t)−265e−tsin(2t) u(t)=(140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t)

Conclusion:

Thus, the time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Answer 6

Chapter 15, Problem 55P

To determine

Find the time-varying function y(t) for the given differential equation using Laplace transform method.

Expert Solution & Answer

Answer to Problem 55P

The time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Explanation of Solution

Given data:

The differential equation is,

d3ydt3+6d2ydt2+8dydt=e−tcos2t (1)

The initial conditions are zero. That is,

y(0)=y'(0)=y''(0)=0

Formula used:

Write the general expression for the Laplace transform.

F(s)=L[f(t)] (2)

Write the general expression for the inverse Laplace transform.

f(t)=L−1[F(s)] (3)

Write the general expressions to find the Laplace transform function.

L[dfdt]=sF(s)−f(0−) (4)

L[d2fdt2]=s2F(s)−sf(0−)−f'(0−) (5)

L[d3fdt3]=s3F(s)−s2f(0−)−sf'(0−)−f''(0−) (6)

L[e−atcosωt]=s+a(s+a)2+ω2 (7)

Here,

s is a complex variable,

ω is the angular frequency, and

s+a is the frequency shift or frequency translation.

Write the general expressions to find the inverse Laplace transform function.

L−1[1s+a]=e−atu(t) (8)

L−1[s+a(s+a)2+ω2]=e−atcosωt u(t) (9)

L−1[ω(s+a)2+ω2]=e−atsinωt u(t) (10)

L−1[1s]=u(t) (11)

Calculation:

Apply Laplace transform function given in equation (2), (4), (5), (6) and (7) to equation (1).

([s3Y(s)−s2y(0−)−sy'(0−)−y''(0−)]+6[s2Y(s)−sy(0−)−y'(0−)]+8[sY(s)−y(0−)])=s+1(s+1)2+22

([s3Y(s)−s2y(0)−sy'(0)−y''(0)]+6[s2Y(s)−sy(0)−y'(0)]+8[sY(s)−y(0)])=s+1(s+1)2+22 {∵y(0−)=y(0), y'(0−)=y'(0)} (12)

Substitute 0 for y(0), 0 for y'(0) and 0 for y''(0) in equation (12).

[s3Y(s)−s2(0)−s(0)−0]+6[s2Y(s)−s(0)−0]+8[sY(s)−0]=s+1(s+1)2+22s3Y(s)+6s2Y(s)+8sY(s)=s+1s2+2s+1+22 {∵(a+b)2=a2+2ab+b2}(s3+6s2+8s)Y(s)=s+1s2+2s+1+4

(s3+6s2+8s)Y(s)=s+1s2+2s+5 (13)

Rearrange the equation (13) to find Y(s).

Y(s)=s+1(s3+6s2+8s)(s2+2s+5)=s+1s(s2+6s+8)(s2+2s+5)=s+1s(s2+2s+4s+8)(s2+2s+5)=s+1s(s(s+2)+4(s+2))(s2+2s+5)

Reduce the equation as follows,

Y(s)=s+1s(s+2)(s+4)(s2+2s+5) (14)

Expand Y(s) using partial fraction.

Y(s)=s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5 (15)

Here,

A, B, C, D and E are the constants.

Now, to find the constants by using residue and algebraic method.

Constant A:

A=sY(s)|s=0 (16)

Substitute equation (14) in equation (16) to find the constant A.

A=s×s+1s(s+2)(s+4)(s2+2s+5)|s=0=s+1(s+2)(s+4)(s2+2s+5)|s=0=0+1(0+2)(0+4)((0)2+2(0)+5)=140

Constant B:

B=(s+2)Y(s)|s+2=0 (17)

Substitute equation (14) in equation (17) to find the constant B.

B=(s+2)×s+1s(s+2)(s+4)(s2+2s+5)|s=−2=s+1s(s+4)(s2+2s+5)|s=−2=−2+1(−2)(−2+4)((−2)2+2(−2)+5)=120

Constant C:

C=(s+4)Y(s)|s+4=0 (18)

Substitute equation (14) in equation (18) to find the constant C.

C=(s+4)×s+1s(s+2)(s+4)(s2+2s+5)|s=−4=s+1s(s+2)(s2+2s+5)|s=−4=−4+1(−4)(−4+2)((−4)2+2(−4)+5)=−3104

Consider the partial fraction,

s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5s+1s(s+2)(s+4)(s2+2s+5)=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s(s+2)(s+4)(s2+2s+5)s+1=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s+1=(A(s2+2s+4s+8)(s2+2s+5)+B(s2+4s)(s2+2s+5)+C(s2+2s)(s2+2s+5)+(Ds+E)s(s2+2s+4s+8))

Reduce the equation as follows,

s+1=(A(s2+6s+8)(s2+2s+5)+B(s4+2s3+5s2+4s3+8s2+20s)+C(s4+2s3+5s2+2s3+4s2+10s)+(Ds+E)(s3+6s2+8s))s+1=(A(s4+2s3+5s2+6s3+12s2+30s+8s2+16s+40)+B(s4+6s3+13s2+20s)+C(s4+4s3+9s2+10s)+D(s4+6s3+8s2)+E(s3+6s2+8s))s+1=(As4+8As3+25As2+46As+40A+Bs4+6Bs3+13Bs2+20Bs+Cs4+4Cs3+9Cs2+10Cs+Ds4+6Ds3+8Ds2+Es3+6Es2+8Es)

s+1=((A+B+C+D)s4+(8A+6B+4C+6D+E)s3+(25A+13B+9C+8D+6E)s2+(46A+20B+10C+8E)s+40A) (19)

Equate the coefficients of s4 in equation (19).

0=A+B+C+D (20)

Substitute 140 for A, 120 for B, and −3104 for C in equation (20) to find the constant D.

0=140+120−3104+DD=−140−120+3104D=−365

Equate the coefficients of s3 in equation (19).

0=8A+6B+4C+6D+E (21)

Substitute 140 for A, 120 for B, −3104 for C, and −365 for D in equation (21) to find the constant E.

0=8(140)+6(120)+4(−3104)+6(−365)+EE=−840−620+12104+1865E=−765

Substitute 140 for A, 120 for B, −3104 for C, −365 for D, and −765 for E in equation (15) to find Y(s).

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)s+(−765)s2+2s+5=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+7)s2+2s+1+4=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3+4)(s+1)2+4 {∵(a+b)2=a2+2ab+b2}

Reduce the equation as follows,

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3)+(−165)4(s+1)2+4=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+4+(−165)4(s+1)2+4

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22 (22)

Apply inverse Laplace transform given in equation (3) to equation (22). Therefore,

y(t)=L−1[Y(s)]=L−1[(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22]={L−1[(140)s]+L−1[(120)s+2]+L−1[(−3104)s+4]+L−1[(−365)(s+1)(s+1)2+22]+L−1[(−265)2(s+1)2+22]}

y(t)={140L−1[1s]+120L−1[1s+2]−3104L−1[1s+4]−365L−1[(s+1)(s+1)2+22]−265L−1[2(s+1)2+22]} (23)

Apply inverse Laplace transform function given in equation (8), (9), (10) and (11) to equation (23).

y(t)=140u(t)+120e−2t u(t)−3104e−4t u(t)−365e−tcos(2t) u(t)−265e−tsin(2t) u(t)=(140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t)

Conclusion:

Thus, the time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Answer 7

Chapter 15, Problem 55P

To determine

Find the time-varying function y(t) for the given differential equation using Laplace transform method.

Answer 8

Expert Solution & Answer

Answer to Problem 55P

The time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given data:

The differential equation is,

d3ydt3+6d2ydt2+8dydt=e−tcos2t (1)

The initial conditions are zero. That is,

y(0)=y'(0)=y''(0)=0

Formula used:

Write the general expression for the Laplace transform.

F(s)=L[f(t)] (2)

Write the general expression for the inverse Laplace transform.

f(t)=L−1[F(s)] (3)

Write the general expressions to find the Laplace transform function.

L[dfdt]=sF(s)−f(0−) (4)

L[d2fdt2]=s2F(s)−sf(0−)−f'(0−) (5)

L[d3fdt3]=s3F(s)−s2f(0−)−sf'(0−)−f''(0−) (6)

L[e−atcosωt]=s+a(s+a)2+ω2 (7)

Here,

s is a complex variable,

ω is the angular frequency, and

s+a is the frequency shift or frequency translation.

Write the general expressions to find the inverse Laplace transform function.

L−1[1s+a]=e−atu(t) (8)

L−1[s+a(s+a)2+ω2]=e−atcosωt u(t) (9)

L−1[ω(s+a)2+ω2]=e−atsinωt u(t) (10)

L−1[1s]=u(t) (11)

Calculation:

Apply Laplace transform function given in equation (2), (4), (5), (6) and (7) to equation (1).

([s3Y(s)−s2y(0−)−sy'(0−)−y''(0−)]+6[s2Y(s)−sy(0−)−y'(0−)]+8[sY(s)−y(0−)])=s+1(s+1)2+22

([s3Y(s)−s2y(0)−sy'(0)−y''(0)]+6[s2Y(s)−sy(0)−y'(0)]+8[sY(s)−y(0)])=s+1(s+1)2+22 {∵y(0−)=y(0), y'(0−)=y'(0)} (12)

Substitute 0 for y(0), 0 for y'(0) and 0 for y''(0) in equation (12).

[s3Y(s)−s2(0)−s(0)−0]+6[s2Y(s)−s(0)−0]+8[sY(s)−0]=s+1(s+1)2+22s3Y(s)+6s2Y(s)+8sY(s)=s+1s2+2s+1+22 {∵(a+b)2=a2+2ab+b2}(s3+6s2+8s)Y(s)=s+1s2+2s+1+4

(s3+6s2+8s)Y(s)=s+1s2+2s+5 (13)

Rearrange the equation (13) to find Y(s).

Y(s)=s+1(s3+6s2+8s)(s2+2s+5)=s+1s(s2+6s+8)(s2+2s+5)=s+1s(s2+2s+4s+8)(s2+2s+5)=s+1s(s(s+2)+4(s+2))(s2+2s+5)

Reduce the equation as follows,

Y(s)=s+1s(s+2)(s+4)(s2+2s+5) (14)

Expand Y(s) using partial fraction.

Y(s)=s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5 (15)

Here,

A, B, C, D and E are the constants.

Now, to find the constants by using residue and algebraic method.

Constant A:

A=sY(s)|s=0 (16)

Substitute equation (14) in equation (16) to find the constant A.

A=s×s+1s(s+2)(s+4)(s2+2s+5)|s=0=s+1(s+2)(s+4)(s2+2s+5)|s=0=0+1(0+2)(0+4)((0)2+2(0)+5)=140

Constant B:

B=(s+2)Y(s)|s+2=0 (17)

Substitute equation (14) in equation (17) to find the constant B.

B=(s+2)×s+1s(s+2)(s+4)(s2+2s+5)|s=−2=s+1s(s+4)(s2+2s+5)|s=−2=−2+1(−2)(−2+4)((−2)2+2(−2)+5)=120

Constant C:

C=(s+4)Y(s)|s+4=0 (18)

Substitute equation (14) in equation (18) to find the constant C.

C=(s+4)×s+1s(s+2)(s+4)(s2+2s+5)|s=−4=s+1s(s+2)(s2+2s+5)|s=−4=−4+1(−4)(−4+2)((−4)2+2(−4)+5)=−3104

Consider the partial fraction,

s+1s(s+2)(s+4)(s2+2s+5)=As+Bs+2+Cs+4+Ds+Es2+2s+5s+1s(s+2)(s+4)(s2+2s+5)=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s(s+2)(s+4)(s2+2s+5)s+1=(A(s+2)(s+4)(s2+2s+5)+Bs(s+4)(s2+2s+5)+Cs(s+2)(s2+2s+5)+(Ds+E)s(s+2)(s+4))s+1=(A(s2+2s+4s+8)(s2+2s+5)+B(s2+4s)(s2+2s+5)+C(s2+2s)(s2+2s+5)+(Ds+E)s(s2+2s+4s+8))

Reduce the equation as follows,

s+1=(A(s2+6s+8)(s2+2s+5)+B(s4+2s3+5s2+4s3+8s2+20s)+C(s4+2s3+5s2+2s3+4s2+10s)+(Ds+E)(s3+6s2+8s))s+1=(A(s4+2s3+5s2+6s3+12s2+30s+8s2+16s+40)+B(s4+6s3+13s2+20s)+C(s4+4s3+9s2+10s)+D(s4+6s3+8s2)+E(s3+6s2+8s))s+1=(As4+8As3+25As2+46As+40A+Bs4+6Bs3+13Bs2+20Bs+Cs4+4Cs3+9Cs2+10Cs+Ds4+6Ds3+8Ds2+Es3+6Es2+8Es)

s+1=((A+B+C+D)s4+(8A+6B+4C+6D+E)s3+(25A+13B+9C+8D+6E)s2+(46A+20B+10C+8E)s+40A) (19)

Equate the coefficients of s4 in equation (19).

0=A+B+C+D (20)

Substitute 140 for A, 120 for B, and −3104 for C in equation (20) to find the constant D.

0=140+120−3104+DD=−140−120+3104D=−365

Equate the coefficients of s3 in equation (19).

0=8A+6B+4C+6D+E (21)

Substitute 140 for A, 120 for B, −3104 for C, and −365 for D in equation (21) to find the constant E.

0=8(140)+6(120)+4(−3104)+6(−365)+EE=−840−620+12104+1865E=−765

Substitute 140 for A, 120 for B, −3104 for C, −365 for D, and −765 for E in equation (15) to find Y(s).

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)s+(−765)s2+2s+5=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+7)s2+2s+1+4=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3+4)(s+1)2+4 {∵(a+b)2=a2+2ab+b2}

Reduce the equation as follows,

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−165)(3s+3)+(−165)4(s+1)2+4=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+4+(−165)4(s+1)2+4

Y(s)=(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22 (22)

Apply inverse Laplace transform given in equation (3) to equation (22). Therefore,

y(t)=L−1[Y(s)]=L−1[(140)s+(120)s+2+(−3104)s+4+(−365)(s+1)(s+1)2+22+(−265)2(s+1)2+22]={L−1[(140)s]+L−1[(120)s+2]+L−1[(−3104)s+4]+L−1[(−365)(s+1)(s+1)2+22]+L−1[(−265)2(s+1)2+22]}

y(t)={140L−1[1s]+120L−1[1s+2]−3104L−1[1s+4]−365L−1[(s+1)(s+1)2+22]−265L−1[2(s+1)2+22]} (23)

Apply inverse Laplace transform function given in equation (8), (9), (10) and (11) to equation (23).

y(t)=140u(t)+120e−2t u(t)−3104e−4t u(t)−365e−tcos(2t) u(t)−265e−tsin(2t) u(t)=(140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t)

Conclusion:

Thus, the time-varying function y(t) for the given differential equation is (140+120e−2t−3104e−4t−365e−tcos(2t)−265e−tsin(2t))u(t).

Answer 12

Ch. 15.2 - Prob. 1PP Ch. 15.2 - Prob. 2PP Ch. 15.3 - Prob. 3PP Ch. 15.3 - Prob. 4PP Ch. 15.3 - Prob. 5PP Ch. 15.3 - Prob. 6PP Ch. 15.3 - Obtain the initial and the final values of...Ch. 15.4 - Prob. 8PP Ch. 15.4 - Find f(t) if F(s)=48(s+2)(s+1)(s+3)(s+4)Ch. 15.4 - Obtain g(t) if G(s)=s3+2s+6s(s+1)2(s+3)

Find the time-varying function y ( t ) for the given differential equation using Laplace transform method.

Concept explainers

Find the time-varying function y(t) for the given differential equation using Laplace transform method.

Answer to Problem 55P

Explanation of Solution

Want to see more full solutions like this?

Chapter 15 Solutions