(a) The inverse Laplace transform f ( t ) of the given function.

Question

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Answer 1

Question

Chapter 2, Problem 2.8P

To determine

(a)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+9 is f(t)=2sin3t.

Explanation of Solution

Given:

F(s)=6s2+9.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+9=2(3)s2+32

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(F(s))⇒f(t)=L−1(6s2+9)⇒f(t)=L−1(2(3)s2+32)⇒f(t)=2sin3t [∵L(sinat)=as2+a2].

To determine

(b)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s2+4+4ss2+4 is f(t)=52sin(2t)+4cos(2t).

Explanation of Solution

Given:

F(s)=5s2+4+4ss2+4.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s2+4+4ss2+4

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s2+4+4ss2+4)⇒f(t)=L−1(5s2+22)+L−1(4ss2+22)⇒f(t)=52L−1(2s2+22)+4L−1(ss2+22)⇒f(t)=52sin(2t)+4cos(2t) [∵L(sinat)=as2+a2&L(cosat)=ss2+a2].

To determine

(c)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+4s+13 is f(t)=2e−2tsin(3t) .

Explanation of Solution

Given:

F(s)=6s2+4s+13.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+4s+13

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(6s2+4s+13)⇒f(t)=L−1(6s2+2(2)s+4+9)⇒f(t)=2L−1(3(s+2)2+32)⇒f(t)=2e−2tsin(3t) [∵L(sinat)=as2+a2&L(e−atf(t))=F(s+a)].

To determine

(d)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s(s+3) is f(t)=53(1−e−3t) .

Explanation of Solution

Given:

F(s)=5s(s+3).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s(s+3)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s(s+3))⇒f(t)=53L−1(3s(s+3))⇒f(t)=53L−1(s+3−ss(s+3))⇒f(t)=53L−1(1s−1(s+3))⇒f(t)=53L−1(1s)−53L−1(1s+3)⇒f(t)=53(1)−53e−3t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=53(1−e−3t) .

To determine

(e)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=10(s+3)(s+7) is f(t)=52(e−3t−e−7t).

Explanation of Solution

Given:

F(s)=10(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=10(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(10(s+3)(s+7)) (1)

Now, we find the partial fraction of 10(s+3)(s+7) such that

10(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)10(s+3)(s+7)=104 (3)B=lims→−7(s+7)10(s+3)(s+7)=−104 (4)

Using (3) and (4) in (1), we get

10(s+3)(s+7)=104(s+3)−104(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(104(s+3)−104(s+7))⇒f(t)=L−1(104(s+3))−L−1(104(s+7))⇒f(t)=52L−1(1s+3)−52L−1(1s+7)⇒f(t)=52e−3t−52e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=52(e−3t−e−7t).

To determine

(f)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=2s+8(s+3)(s+7) is f(t)=12e−3t+32e−7t.

Explanation of Solution

Given:

F(s)=2s+8(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=2s+8(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(2s+8(s+3)(s+7)) (1)

Now, we find the partial fraction of 2s+8(s+3)(s+7) such that

2s+8(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)2s+8(s+3)(s+7)=2(−3)+84=12 (3)B=lims→−7(s+7)2s+8(s+3)(s+7)=2(−7)+8−4=32 (4)

Using (3) and (4) in (1), we get

2s+8(s+3)(s+7)=12(s+3)+32(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(12(s+3)+32(s+7))⇒f(t)=L−1(12(s+3))+L−1(32(s+7))⇒f(t)=12L−1(1s+3)+32L−1(1s+7)⇒f(t)=12e−3t+32e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)].

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Answer 2

Question

Chapter 2, Problem 2.8P

To determine

(a)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+9 is f(t)=2sin3t.

Explanation of Solution

Given:

F(s)=6s2+9.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+9=2(3)s2+32

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(F(s))⇒f(t)=L−1(6s2+9)⇒f(t)=L−1(2(3)s2+32)⇒f(t)=2sin3t [∵L(sinat)=as2+a2].

To determine

(b)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s2+4+4ss2+4 is f(t)=52sin(2t)+4cos(2t).

Explanation of Solution

Given:

F(s)=5s2+4+4ss2+4.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s2+4+4ss2+4

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s2+4+4ss2+4)⇒f(t)=L−1(5s2+22)+L−1(4ss2+22)⇒f(t)=52L−1(2s2+22)+4L−1(ss2+22)⇒f(t)=52sin(2t)+4cos(2t) [∵L(sinat)=as2+a2&L(cosat)=ss2+a2].

To determine

(c)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+4s+13 is f(t)=2e−2tsin(3t) .

Explanation of Solution

Given:

F(s)=6s2+4s+13.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+4s+13

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(6s2+4s+13)⇒f(t)=L−1(6s2+2(2)s+4+9)⇒f(t)=2L−1(3(s+2)2+32)⇒f(t)=2e−2tsin(3t) [∵L(sinat)=as2+a2&L(e−atf(t))=F(s+a)].

To determine

(d)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s(s+3) is f(t)=53(1−e−3t) .

Explanation of Solution

Given:

F(s)=5s(s+3).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s(s+3)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s(s+3))⇒f(t)=53L−1(3s(s+3))⇒f(t)=53L−1(s+3−ss(s+3))⇒f(t)=53L−1(1s−1(s+3))⇒f(t)=53L−1(1s)−53L−1(1s+3)⇒f(t)=53(1)−53e−3t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=53(1−e−3t) .

To determine

(e)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=10(s+3)(s+7) is f(t)=52(e−3t−e−7t).

Explanation of Solution

Given:

F(s)=10(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=10(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(10(s+3)(s+7)) (1)

Now, we find the partial fraction of 10(s+3)(s+7) such that

10(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)10(s+3)(s+7)=104 (3)B=lims→−7(s+7)10(s+3)(s+7)=−104 (4)

Using (3) and (4) in (1), we get

10(s+3)(s+7)=104(s+3)−104(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(104(s+3)−104(s+7))⇒f(t)=L−1(104(s+3))−L−1(104(s+7))⇒f(t)=52L−1(1s+3)−52L−1(1s+7)⇒f(t)=52e−3t−52e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=52(e−3t−e−7t).

To determine

(f)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=2s+8(s+3)(s+7) is f(t)=12e−3t+32e−7t.

Explanation of Solution

Given:

F(s)=2s+8(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=2s+8(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(2s+8(s+3)(s+7)) (1)

Now, we find the partial fraction of 2s+8(s+3)(s+7) such that

2s+8(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)2s+8(s+3)(s+7)=2(−3)+84=12 (3)B=lims→−7(s+7)2s+8(s+3)(s+7)=2(−7)+8−4=32 (4)

Using (3) and (4) in (1), we get

2s+8(s+3)(s+7)=12(s+3)+32(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(12(s+3)+32(s+7))⇒f(t)=L−1(12(s+3))+L−1(32(s+7))⇒f(t)=12L−1(1s+3)+32L−1(1s+7)⇒f(t)=12e−3t+32e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)].

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Answer 3

Question

Chapter 2, Problem 2.8P

To determine

(a)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+9 is f(t)=2sin3t.

Explanation of Solution

Given:

F(s)=6s2+9.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+9=2(3)s2+32

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(F(s))⇒f(t)=L−1(6s2+9)⇒f(t)=L−1(2(3)s2+32)⇒f(t)=2sin3t [∵L(sinat)=as2+a2].

To determine

(b)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s2+4+4ss2+4 is f(t)=52sin(2t)+4cos(2t).

Explanation of Solution

Given:

F(s)=5s2+4+4ss2+4.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s2+4+4ss2+4

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s2+4+4ss2+4)⇒f(t)=L−1(5s2+22)+L−1(4ss2+22)⇒f(t)=52L−1(2s2+22)+4L−1(ss2+22)⇒f(t)=52sin(2t)+4cos(2t) [∵L(sinat)=as2+a2&L(cosat)=ss2+a2].

To determine

(c)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+4s+13 is f(t)=2e−2tsin(3t) .

Explanation of Solution

Given:

F(s)=6s2+4s+13.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+4s+13

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(6s2+4s+13)⇒f(t)=L−1(6s2+2(2)s+4+9)⇒f(t)=2L−1(3(s+2)2+32)⇒f(t)=2e−2tsin(3t) [∵L(sinat)=as2+a2&L(e−atf(t))=F(s+a)].

To determine

(d)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s(s+3) is f(t)=53(1−e−3t) .

Explanation of Solution

Given:

F(s)=5s(s+3).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s(s+3)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s(s+3))⇒f(t)=53L−1(3s(s+3))⇒f(t)=53L−1(s+3−ss(s+3))⇒f(t)=53L−1(1s−1(s+3))⇒f(t)=53L−1(1s)−53L−1(1s+3)⇒f(t)=53(1)−53e−3t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=53(1−e−3t) .

To determine

(e)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=10(s+3)(s+7) is f(t)=52(e−3t−e−7t).

Explanation of Solution

Given:

F(s)=10(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=10(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(10(s+3)(s+7)) (1)

Now, we find the partial fraction of 10(s+3)(s+7) such that

10(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)10(s+3)(s+7)=104 (3)B=lims→−7(s+7)10(s+3)(s+7)=−104 (4)

Using (3) and (4) in (1), we get

10(s+3)(s+7)=104(s+3)−104(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(104(s+3)−104(s+7))⇒f(t)=L−1(104(s+3))−L−1(104(s+7))⇒f(t)=52L−1(1s+3)−52L−1(1s+7)⇒f(t)=52e−3t−52e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=52(e−3t−e−7t).

To determine

(f)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=2s+8(s+3)(s+7) is f(t)=12e−3t+32e−7t.

Explanation of Solution

Given:

F(s)=2s+8(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=2s+8(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(2s+8(s+3)(s+7)) (1)

Now, we find the partial fraction of 2s+8(s+3)(s+7) such that

2s+8(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)2s+8(s+3)(s+7)=2(−3)+84=12 (3)B=lims→−7(s+7)2s+8(s+3)(s+7)=2(−7)+8−4=32 (4)

Using (3) and (4) in (1), we get

2s+8(s+3)(s+7)=12(s+3)+32(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(12(s+3)+32(s+7))⇒f(t)=L−1(12(s+3))+L−1(32(s+7))⇒f(t)=12L−1(1s+3)+32L−1(1s+7)⇒f(t)=12e−3t+32e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)].

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Answer 4

Question

Chapter 2, Problem 2.8P

To determine

(a)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+9 is f(t)=2sin3t.

Explanation of Solution

Given:

F(s)=6s2+9.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+9=2(3)s2+32

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(F(s))⇒f(t)=L−1(6s2+9)⇒f(t)=L−1(2(3)s2+32)⇒f(t)=2sin3t [∵L(sinat)=as2+a2].

To determine

(b)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s2+4+4ss2+4 is f(t)=52sin(2t)+4cos(2t).

Explanation of Solution

Given:

F(s)=5s2+4+4ss2+4.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s2+4+4ss2+4

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s2+4+4ss2+4)⇒f(t)=L−1(5s2+22)+L−1(4ss2+22)⇒f(t)=52L−1(2s2+22)+4L−1(ss2+22)⇒f(t)=52sin(2t)+4cos(2t) [∵L(sinat)=as2+a2&L(cosat)=ss2+a2].

To determine

(c)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+4s+13 is f(t)=2e−2tsin(3t) .

Explanation of Solution

Given:

F(s)=6s2+4s+13.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+4s+13

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(6s2+4s+13)⇒f(t)=L−1(6s2+2(2)s+4+9)⇒f(t)=2L−1(3(s+2)2+32)⇒f(t)=2e−2tsin(3t) [∵L(sinat)=as2+a2&L(e−atf(t))=F(s+a)].

To determine

(d)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s(s+3) is f(t)=53(1−e−3t) .

Explanation of Solution

Given:

F(s)=5s(s+3).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s(s+3)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s(s+3))⇒f(t)=53L−1(3s(s+3))⇒f(t)=53L−1(s+3−ss(s+3))⇒f(t)=53L−1(1s−1(s+3))⇒f(t)=53L−1(1s)−53L−1(1s+3)⇒f(t)=53(1)−53e−3t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=53(1−e−3t) .

To determine

(e)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=10(s+3)(s+7) is f(t)=52(e−3t−e−7t).

Explanation of Solution

Given:

F(s)=10(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=10(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(10(s+3)(s+7)) (1)

Now, we find the partial fraction of 10(s+3)(s+7) such that

10(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)10(s+3)(s+7)=104 (3)B=lims→−7(s+7)10(s+3)(s+7)=−104 (4)

Using (3) and (4) in (1), we get

10(s+3)(s+7)=104(s+3)−104(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(104(s+3)−104(s+7))⇒f(t)=L−1(104(s+3))−L−1(104(s+7))⇒f(t)=52L−1(1s+3)−52L−1(1s+7)⇒f(t)=52e−3t−52e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=52(e−3t−e−7t).

To determine

(f)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=2s+8(s+3)(s+7) is f(t)=12e−3t+32e−7t.

Explanation of Solution

Given:

F(s)=2s+8(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=2s+8(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(2s+8(s+3)(s+7)) (1)

Now, we find the partial fraction of 2s+8(s+3)(s+7) such that

2s+8(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)2s+8(s+3)(s+7)=2(−3)+84=12 (3)B=lims→−7(s+7)2s+8(s+3)(s+7)=2(−7)+8−4=32 (4)

Using (3) and (4) in (1), we get

2s+8(s+3)(s+7)=12(s+3)+32(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(12(s+3)+32(s+7))⇒f(t)=L−1(12(s+3))+L−1(32(s+7))⇒f(t)=12L−1(1s+3)+32L−1(1s+7)⇒f(t)=12e−3t+32e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)].

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Answer 5

Chapter 2, Problem 2.8P

To determine

(a)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+9 is f(t)=2sin3t.

Explanation of Solution

Given:

F(s)=6s2+9.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+9=2(3)s2+32

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(F(s))⇒f(t)=L−1(6s2+9)⇒f(t)=L−1(2(3)s2+32)⇒f(t)=2sin3t [∵L(sinat)=as2+a2].

To determine

(b)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s2+4+4ss2+4 is f(t)=52sin(2t)+4cos(2t).

Explanation of Solution

Given:

F(s)=5s2+4+4ss2+4.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s2+4+4ss2+4

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s2+4+4ss2+4)⇒f(t)=L−1(5s2+22)+L−1(4ss2+22)⇒f(t)=52L−1(2s2+22)+4L−1(ss2+22)⇒f(t)=52sin(2t)+4cos(2t) [∵L(sinat)=as2+a2&L(cosat)=ss2+a2].

To determine

(c)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+4s+13 is f(t)=2e−2tsin(3t) .

Explanation of Solution

Given:

F(s)=6s2+4s+13.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+4s+13

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(6s2+4s+13)⇒f(t)=L−1(6s2+2(2)s+4+9)⇒f(t)=2L−1(3(s+2)2+32)⇒f(t)=2e−2tsin(3t) [∵L(sinat)=as2+a2&L(e−atf(t))=F(s+a)].

To determine

(d)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s(s+3) is f(t)=53(1−e−3t) .

Explanation of Solution

Given:

F(s)=5s(s+3).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s(s+3)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s(s+3))⇒f(t)=53L−1(3s(s+3))⇒f(t)=53L−1(s+3−ss(s+3))⇒f(t)=53L−1(1s−1(s+3))⇒f(t)=53L−1(1s)−53L−1(1s+3)⇒f(t)=53(1)−53e−3t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=53(1−e−3t) .

To determine

(e)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=10(s+3)(s+7) is f(t)=52(e−3t−e−7t).

Explanation of Solution

Given:

F(s)=10(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=10(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(10(s+3)(s+7)) (1)

Now, we find the partial fraction of 10(s+3)(s+7) such that

10(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)10(s+3)(s+7)=104 (3)B=lims→−7(s+7)10(s+3)(s+7)=−104 (4)

Using (3) and (4) in (1), we get

10(s+3)(s+7)=104(s+3)−104(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(104(s+3)−104(s+7))⇒f(t)=L−1(104(s+3))−L−1(104(s+7))⇒f(t)=52L−1(1s+3)−52L−1(1s+7)⇒f(t)=52e−3t−52e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=52(e−3t−e−7t).

To determine

(f)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=2s+8(s+3)(s+7) is f(t)=12e−3t+32e−7t.

Explanation of Solution

Given:

F(s)=2s+8(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=2s+8(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(2s+8(s+3)(s+7)) (1)

Now, we find the partial fraction of 2s+8(s+3)(s+7) such that

2s+8(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)2s+8(s+3)(s+7)=2(−3)+84=12 (3)B=lims→−7(s+7)2s+8(s+3)(s+7)=2(−7)+8−4=32 (4)

Using (3) and (4) in (1), we get

2s+8(s+3)(s+7)=12(s+3)+32(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(12(s+3)+32(s+7))⇒f(t)=L−1(12(s+3))+L−1(32(s+7))⇒f(t)=12L−1(1s+3)+32L−1(1s+7)⇒f(t)=12e−3t+32e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)].

Answer 6

Chapter 2, Problem 2.8P

To determine

(a)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+9 is f(t)=2sin3t.

Explanation of Solution

Given:

F(s)=6s2+9.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+9=2(3)s2+32

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(F(s))⇒f(t)=L−1(6s2+9)⇒f(t)=L−1(2(3)s2+32)⇒f(t)=2sin3t [∵L(sinat)=as2+a2].

Answer 7

Chapter 2, Problem 2.8P

To determine

(a)

The inverse Laplace transform f(t) of the given function.

Answer 8

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+9 is f(t)=2sin3t.

Answer 9

Expert Solution

Answer 10

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given:

F(s)=6s2+9.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+9=2(3)s2+32

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(F(s))⇒f(t)=L−1(6s2+9)⇒f(t)=L−1(2(3)s2+32)⇒f(t)=2sin3t [∵L(sinat)=as2+a2].

Answer 13

To determine

(b)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s2+4+4ss2+4 is f(t)=52sin(2t)+4cos(2t).

Explanation of Solution

Given:

F(s)=5s2+4+4ss2+4.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s2+4+4ss2+4

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s2+4+4ss2+4)⇒f(t)=L−1(5s2+22)+L−1(4ss2+22)⇒f(t)=52L−1(2s2+22)+4L−1(ss2+22)⇒f(t)=52sin(2t)+4cos(2t) [∵L(sinat)=as2+a2&L(cosat)=ss2+a2].

Answer 14

To determine

(b)

The inverse Laplace transform f(t) of the given function.

Answer 15

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s2+4+4ss2+4 is f(t)=52sin(2t)+4cos(2t).

Answer 16

Expert Solution

Answer 17

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Given:

F(s)=5s2+4+4ss2+4.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s2+4+4ss2+4

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s2+4+4ss2+4)⇒f(t)=L−1(5s2+22)+L−1(4ss2+22)⇒f(t)=52L−1(2s2+22)+4L−1(ss2+22)⇒f(t)=52sin(2t)+4cos(2t) [∵L(sinat)=as2+a2&L(cosat)=ss2+a2].

Answer 20

To determine

(c)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+4s+13 is f(t)=2e−2tsin(3t) .

Explanation of Solution

Given:

F(s)=6s2+4s+13.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+4s+13

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(6s2+4s+13)⇒f(t)=L−1(6s2+2(2)s+4+9)⇒f(t)=2L−1(3(s+2)2+32)⇒f(t)=2e−2tsin(3t) [∵L(sinat)=as2+a2&L(e−atf(t))=F(s+a)].

Answer 21

To determine

(c)

The inverse Laplace transform f(t) of the given function.

Answer 22

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=6s2+4s+13 is f(t)=2e−2tsin(3t) .

Answer 23

Expert Solution

Answer 24

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

Given:

F(s)=6s2+4s+13.

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(sinat)=L(eiat−e−iat2i)=as2+a2L(cosat)=L(eiat+e−iat2)=ss2+a2L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=6s2+4s+13

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(6s2+4s+13)⇒f(t)=L−1(6s2+2(2)s+4+9)⇒f(t)=2L−1(3(s+2)2+32)⇒f(t)=2e−2tsin(3t) [∵L(sinat)=as2+a2&L(e−atf(t))=F(s+a)].

Answer 27

To determine

(d)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s(s+3) is f(t)=53(1−e−3t) .

Explanation of Solution

Given:

F(s)=5s(s+3).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s(s+3)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s(s+3))⇒f(t)=53L−1(3s(s+3))⇒f(t)=53L−1(s+3−ss(s+3))⇒f(t)=53L−1(1s−1(s+3))⇒f(t)=53L−1(1s)−53L−1(1s+3)⇒f(t)=53(1)−53e−3t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=53(1−e−3t) .

Answer 28

To determine

(d)

The inverse Laplace transform f(t) of the given function.

Answer 29

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=5s(s+3) is f(t)=53(1−e−3t) .

Answer 30

Expert Solution

Answer 31

Expert Solution

Answer 32

Expert Solution

Answer 33

Explanation of Solution

Given:

F(s)=5s(s+3).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=5s(s+3)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(5s(s+3))⇒f(t)=53L−1(3s(s+3))⇒f(t)=53L−1(s+3−ss(s+3))⇒f(t)=53L−1(1s−1(s+3))⇒f(t)=53L−1(1s)−53L−1(1s+3)⇒f(t)=53(1)−53e−3t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=53(1−e−3t) .

Answer 34

To determine

(e)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=10(s+3)(s+7) is f(t)=52(e−3t−e−7t).

Explanation of Solution

Given:

F(s)=10(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=10(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(10(s+3)(s+7)) (1)

Now, we find the partial fraction of 10(s+3)(s+7) such that

10(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)10(s+3)(s+7)=104 (3)B=lims→−7(s+7)10(s+3)(s+7)=−104 (4)

Using (3) and (4) in (1), we get

10(s+3)(s+7)=104(s+3)−104(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(104(s+3)−104(s+7))⇒f(t)=L−1(104(s+3))−L−1(104(s+7))⇒f(t)=52L−1(1s+3)−52L−1(1s+7)⇒f(t)=52e−3t−52e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=52(e−3t−e−7t).

Answer 35

To determine

(e)

The inverse Laplace transform f(t) of the given function.

Answer 36

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=10(s+3)(s+7) is f(t)=52(e−3t−e−7t).

Answer 37

Expert Solution

Answer 38

Expert Solution

Answer 39

Expert Solution

Answer 40

Explanation of Solution

Given:

F(s)=10(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=10(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(10(s+3)(s+7)) (1)

Now, we find the partial fraction of 10(s+3)(s+7) such that

10(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)10(s+3)(s+7)=104 (3)B=lims→−7(s+7)10(s+3)(s+7)=−104 (4)

Using (3) and (4) in (1), we get

10(s+3)(s+7)=104(s+3)−104(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(104(s+3)−104(s+7))⇒f(t)=L−1(104(s+3))−L−1(104(s+7))⇒f(t)=52L−1(1s+3)−52L−1(1s+7)⇒f(t)=52e−3t−52e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)]⇒f(t)=52(e−3t−e−7t).

Answer 41

To determine

(f)

The inverse Laplace transform f(t) of the given function.

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=2s+8(s+3)(s+7) is f(t)=12e−3t+32e−7t.

Explanation of Solution

Given:

F(s)=2s+8(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=2s+8(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(2s+8(s+3)(s+7)) (1)

Now, we find the partial fraction of 2s+8(s+3)(s+7) such that

2s+8(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)2s+8(s+3)(s+7)=2(−3)+84=12 (3)B=lims→−7(s+7)2s+8(s+3)(s+7)=2(−7)+8−4=32 (4)

Using (3) and (4) in (1), we get

2s+8(s+3)(s+7)=12(s+3)+32(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(12(s+3)+32(s+7))⇒f(t)=L−1(12(s+3))+L−1(32(s+7))⇒f(t)=12L−1(1s+3)+32L−1(1s+7)⇒f(t)=12e−3t+32e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)].

Answer 42

To determine

(f)

The inverse Laplace transform f(t) of the given function.

Answer 43

Expert Solution

Answer to Problem 2.8P

Inverse Laplace transform of the function F(s)=2s+8(s+3)(s+7) is f(t)=12e−3t+32e−7t.

Answer 44

Expert Solution

Answer 45

Expert Solution

Answer 46

Expert Solution

Answer 47

Explanation of Solution

Given:

F(s)=2s+8(s+3)(s+7).

Concept Used:

Laplace transform of function f(t) is defined as

L(f(t))=∫0∞e−stf(t)dt

Where f(t) is piecewise continuo function defined for all t≥0.

L(tn)=n+1sn+1=nsn+1L(e−atf(t))=F(s+a);L(f(t))=F(s)L(tnf(t))=(−1)ndndsn(F(s));L(f(t))=F(s)

Inverse Laplace transform of given function F(s) is given by

f(t)=L−1(F(s)).

Calculation:

Here, we have

F(s)=2s+8(s+3)(s+7)

Thus, the inverse Laplace transform f(t) of the given function is given as

f(t)=L−1(2s+8(s+3)(s+7)) (1)

Now, we find the partial fraction of 2s+8(s+3)(s+7) such that

2s+8(s+3)(s+7)=A(s+3)+B(s+7) (2)

Here, A and B will be

A=lims→−3(s+3)2s+8(s+3)(s+7)=2(−3)+84=12 (3)B=lims→−7(s+7)2s+8(s+3)(s+7)=2(−7)+8−4=32 (4)

Using (3) and (4) in (1), we get

2s+8(s+3)(s+7)=12(s+3)+32(s+7) (5)

Using (5) in (1), we get

f(t)=L−1(12(s+3)+32(s+7))⇒f(t)=L−1(12(s+3))+L−1(32(s+7))⇒f(t)=12L−1(1s+3)+32L−1(1s+7)⇒f(t)=12e−3t+32e−7t [∵L(1)=1s&L(e−atf(t))=F(s+a)].

Answer 48

Ch. 2 - Prob. 2.1P Ch. 2 - Solve each of the following problems by direct...Ch. 2 - Solve each of the following problems by separation...Ch. 2 - Prob. 2.4P Ch. 2 - Prob. 2.5P Ch. 2 - Obtain the Laplace transform of the following...Ch. 2 - Obtain the Laplace transform of the function shown...Ch. 2 - Prob. 2.8P Ch. 2 - Prob. 2.9P Ch. 2 - Prob. 2.10P

(a) The inverse Laplace transform f ( t ) of the given function.

Concept explainers

Videos

(a)

The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(b)

The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(c)

The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(d)

The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(e)

The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(f)

The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

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Chapter 2 Solutions

(a) The inverse Laplace transform f ( t ) of the given function.

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Videos

(a) The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(b) The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(c) The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(d) The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(e) The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

(f) The inverse Laplace transform f(t) of the given function.

Answer to Problem 2.8P

Explanation of Solution

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Chapter 2 Solutions

(a)

The inverse Laplace transform f(t) of the given function.

(b)

The inverse Laplace transform f(t) of the given function.

(c)

The inverse Laplace transform f(t) of the given function.

(d)

The inverse Laplace transform f(t) of the given function.

(e)

The inverse Laplace transform f(t) of the given function.

(f)

The inverse Laplace transform f(t) of the given function.