Sketch the line spectrum for the waveform shown in Figure 17.31.

Question

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Answer 1

Question

Chapter 17, Problem 15E

To determine

Sketch the line spectrum for the waveform shown in Figure 17.31.

Expert Solution & Answer

Answer to Problem 15E

The line spectrum for the given waveform is sketched as shown in Figure 1.

Explanation of Solution

Given data:

Refer to Figure 17.31 in the textbook.

Formula used:

Write the general expression for Fourier series expansion.

f(t)=a0+∑n=1∞(ancosnω0t+bnsinnω0t) (1)

Write the general expression for Fourier series coefficient a0.

a0=1T∫0Tf(t)dt (2)

Write the general expression for Fourier series coefficient an.

an=2T∫0Tf(t)cosnω0tdt (3)

Write the general expression for Fourier series coefficient bn.

bn=2T∫0Tf(t)sinnω0tdt (4)

Write the expression to calculate the fundamental angular frequency.

ω0=2πT=2πf0 (5)

Here,

T is the period of the function.

Calculation:

In the given Figure 17.31, the time period is T=0.4.

The function v(t) for the given waveform is,

v(t)={Vmcos5πt, −0.1≤t≤0.10, 0.1≤t≤0.3 (6)

Substitute 0.4 for T in equation (5) to find ω0.

ω0=2π0.4

ω0=5π (7)

Applying equation (6) in equation (2) to find a0 as follows,

a0=10.4∫00.4v(t)dt=10.4[∫−0.10.1Vmcos5πtdt+∫0.10.3(0)dt+]=Vm0.4[sin5πt5π]−0.10.1=Vm0.4[sin5π(0.1)5π−sin5π(−0.1)5π]=Vm0.4[1+15π]

Simplify the above equation as follows,

a0=Vmπ

For half wave symmetry and even symmetry,

For all values of ‘n’, bn=0.

Applying equation (6) in equation (3) to find the value of coefficient an.

an=20.4∫00.4v(t)cosnω0tdt

an=2Vm0.4[∫−0.10.1cos(5πt)cos(5πnt)dt] {∵ω0=5π} (8)

Consider the function,

x=∫cos(5πt)cos(5πnt)dt

Consider,

u=5πt

On differentiating the above expression,

dudt=5πdt=du5π

Equation (8) will be follows,

x=15π∫cos(u)cos(nu)du (9)

In the above equation, consider,

y=∫cos(u)cos(nu)du=∫cos(nu+u)+cos(nu−u)2du {∵cos(x)cos(y)=12[cos(y+x)+cos(y−x)]}=∫cos((n+1)u)+cos((n−1)u)2du

By applying linearity,

y=12∫cos((n+1)u)du+12∫cos((n−1)u)du (10)

In equation (10),

consider,

m=∫cos((n+1)u)du (11)

Let,

v=(n+1)udvdu=(n+1)du=dvn+1

Equation (11) will be as follows,

m=1n+1∫cos(v)dv=sin(v)n+1=sin((n+1)u)n+1 {∵v=(n+1)u}

Similarly, in equation (10),

consider,

l=∫cos((n−1)u)du (12)

Let,

v=(n−1)udvdu=(n−1)du=dvn−1

Equation (12) will be as follows,

l=1n−1∫cos(v)dv=sin(v)n−1=sin((n−1)u)n−1 v=(n−1)u

Substitute the values of m and l in equation (10) as follows,

y=12[sin((n+1)u)n+1+sin((n−1)u)n−1]=sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)

Substitute the value of y in equation (9) as follows,

x=15π[sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)]=sin((n+1)u)10π(n+1)+sin((n−1)u)10π(n−1)=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1) {∵u=5πt}

Therefore,

∫cos(5πt)cos(5πnt)dt=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1)=(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)

On applying the limits,

∫−0.10.1cos(5πt)cos(5πnt)dt=[(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)]−0.10.1=[(n−1)sin(5π(n+1)(0.1))+(n+1)sin(5π(n−1)(0.1))10π(n2−1)]−[(n−1)sin(5π(n+1)(−0.1))+(n+1)sin(5π(n−1)(−0.1))10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]−[−(n−1)sin(nπ+π2)−(n+1)sin(nπ−π2)10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]+ [(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)]10π(n2−1)=2[(n−1)sin(nπ2+π2)+(n+1)sin(nπ2−π2)]10π(n2−1)=2[(n−1)cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1) {∵sin(90+θ)=cosθ,sin(−θ)=−sinθ}=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1)

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(nπ2)]10π(n2−1) {∵cos(−θ)=cosθ}=2[ncos(nπ2)−cos(nπ2)−ncos(nπ2)−cos(nπ2)]10π(n2−1)=2[−2cos(nπ2)]10π(n2−1)=−2cos(nπ2)5π(n2−1)

Substitute the value of ∫−0.10.1cos(5πt)cos(5πnt)dt in equation (8) as follows,

an=2Vm0.4[−2cos(nπ2)5π(n2−1)] =−2Vmcos(nπ2)π(n2−1)

an=2Vmπcos(nπ2)(1−n2) (n≠1)

Converting the equation (1) which is in angular frequency into frequency.

v(t)=a0+∑n=1∞(ancosnf0t+bnsinnf0t) (13)

Substitute the value of a0, an, and bn in equation (13) as follows,

v(t)=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(5π2π)t+0) {∵ f0=ω02π, ω0=5π}=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(52)t)

By considering Vm=1 V, the above equation will be as follows,

v(t)=1π+∑n=1∞((2π)(cos(nπ2)1−n2)cosn(52)t) (14)

For n=0, the equation (14) will be as follows,

v(t)=1π

For n=2, the equation (14) will be as follows,

v(t)=1π+(2π)(cos(2π2)1−(2)2)cos(2)(52)t=1π+(2π)(−1−3)cos(5)t=1π+(2π)(−1−3)cos(5)t=1π+0.2cos5t

The sketch for the line spectrum is shown in Figure 1.

Engineering Circuit Analysis, Chapter 17, Problem 15E

Conclusion:

Thus, the line spectrum for the given waveform is sketched as shown in Figure 1.

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Answer 2

Question

Chapter 17, Problem 15E

To determine

Sketch the line spectrum for the waveform shown in Figure 17.31.

Expert Solution & Answer

Answer to Problem 15E

The line spectrum for the given waveform is sketched as shown in Figure 1.

Explanation of Solution

Given data:

Refer to Figure 17.31 in the textbook.

Formula used:

Write the general expression for Fourier series expansion.

f(t)=a0+∑n=1∞(ancosnω0t+bnsinnω0t) (1)

Write the general expression for Fourier series coefficient a0.

a0=1T∫0Tf(t)dt (2)

Write the general expression for Fourier series coefficient an.

an=2T∫0Tf(t)cosnω0tdt (3)

Write the general expression for Fourier series coefficient bn.

bn=2T∫0Tf(t)sinnω0tdt (4)

Write the expression to calculate the fundamental angular frequency.

ω0=2πT=2πf0 (5)

Here,

T is the period of the function.

Calculation:

In the given Figure 17.31, the time period is T=0.4.

The function v(t) for the given waveform is,

v(t)={Vmcos5πt, −0.1≤t≤0.10, 0.1≤t≤0.3 (6)

Substitute 0.4 for T in equation (5) to find ω0.

ω0=2π0.4

ω0=5π (7)

Applying equation (6) in equation (2) to find a0 as follows,

a0=10.4∫00.4v(t)dt=10.4[∫−0.10.1Vmcos5πtdt+∫0.10.3(0)dt+]=Vm0.4[sin5πt5π]−0.10.1=Vm0.4[sin5π(0.1)5π−sin5π(−0.1)5π]=Vm0.4[1+15π]

Simplify the above equation as follows,

a0=Vmπ

For half wave symmetry and even symmetry,

For all values of ‘n’, bn=0.

Applying equation (6) in equation (3) to find the value of coefficient an.

an=20.4∫00.4v(t)cosnω0tdt

an=2Vm0.4[∫−0.10.1cos(5πt)cos(5πnt)dt] {∵ω0=5π} (8)

Consider the function,

x=∫cos(5πt)cos(5πnt)dt

Consider,

u=5πt

On differentiating the above expression,

dudt=5πdt=du5π

Equation (8) will be follows,

x=15π∫cos(u)cos(nu)du (9)

In the above equation, consider,

y=∫cos(u)cos(nu)du=∫cos(nu+u)+cos(nu−u)2du {∵cos(x)cos(y)=12[cos(y+x)+cos(y−x)]}=∫cos((n+1)u)+cos((n−1)u)2du

By applying linearity,

y=12∫cos((n+1)u)du+12∫cos((n−1)u)du (10)

In equation (10),

consider,

m=∫cos((n+1)u)du (11)

Let,

v=(n+1)udvdu=(n+1)du=dvn+1

Equation (11) will be as follows,

m=1n+1∫cos(v)dv=sin(v)n+1=sin((n+1)u)n+1 {∵v=(n+1)u}

Similarly, in equation (10),

consider,

l=∫cos((n−1)u)du (12)

Let,

v=(n−1)udvdu=(n−1)du=dvn−1

Equation (12) will be as follows,

l=1n−1∫cos(v)dv=sin(v)n−1=sin((n−1)u)n−1 v=(n−1)u

Substitute the values of m and l in equation (10) as follows,

y=12[sin((n+1)u)n+1+sin((n−1)u)n−1]=sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)

Substitute the value of y in equation (9) as follows,

x=15π[sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)]=sin((n+1)u)10π(n+1)+sin((n−1)u)10π(n−1)=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1) {∵u=5πt}

Therefore,

∫cos(5πt)cos(5πnt)dt=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1)=(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)

On applying the limits,

∫−0.10.1cos(5πt)cos(5πnt)dt=[(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)]−0.10.1=[(n−1)sin(5π(n+1)(0.1))+(n+1)sin(5π(n−1)(0.1))10π(n2−1)]−[(n−1)sin(5π(n+1)(−0.1))+(n+1)sin(5π(n−1)(−0.1))10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]−[−(n−1)sin(nπ+π2)−(n+1)sin(nπ−π2)10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]+ [(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)]10π(n2−1)=2[(n−1)sin(nπ2+π2)+(n+1)sin(nπ2−π2)]10π(n2−1)=2[(n−1)cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1) {∵sin(90+θ)=cosθ,sin(−θ)=−sinθ}=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1)

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(nπ2)]10π(n2−1) {∵cos(−θ)=cosθ}=2[ncos(nπ2)−cos(nπ2)−ncos(nπ2)−cos(nπ2)]10π(n2−1)=2[−2cos(nπ2)]10π(n2−1)=−2cos(nπ2)5π(n2−1)

Substitute the value of ∫−0.10.1cos(5πt)cos(5πnt)dt in equation (8) as follows,

an=2Vm0.4[−2cos(nπ2)5π(n2−1)] =−2Vmcos(nπ2)π(n2−1)

an=2Vmπcos(nπ2)(1−n2) (n≠1)

Converting the equation (1) which is in angular frequency into frequency.

v(t)=a0+∑n=1∞(ancosnf0t+bnsinnf0t) (13)

Substitute the value of a0, an, and bn in equation (13) as follows,

v(t)=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(5π2π)t+0) {∵ f0=ω02π, ω0=5π}=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(52)t)

By considering Vm=1 V, the above equation will be as follows,

v(t)=1π+∑n=1∞((2π)(cos(nπ2)1−n2)cosn(52)t) (14)

For n=0, the equation (14) will be as follows,

v(t)=1π

For n=2, the equation (14) will be as follows,

v(t)=1π+(2π)(cos(2π2)1−(2)2)cos(2)(52)t=1π+(2π)(−1−3)cos(5)t=1π+(2π)(−1−3)cos(5)t=1π+0.2cos5t

The sketch for the line spectrum is shown in Figure 1.

Engineering Circuit Analysis, Chapter 17, Problem 15E

Conclusion:

Thus, the line spectrum for the given waveform is sketched as shown in Figure 1.

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Answer 3

Question

Chapter 17, Problem 15E

To determine

Sketch the line spectrum for the waveform shown in Figure 17.31.

Expert Solution & Answer

Answer to Problem 15E

The line spectrum for the given waveform is sketched as shown in Figure 1.

Explanation of Solution

Given data:

Refer to Figure 17.31 in the textbook.

Formula used:

Write the general expression for Fourier series expansion.

f(t)=a0+∑n=1∞(ancosnω0t+bnsinnω0t) (1)

Write the general expression for Fourier series coefficient a0.

a0=1T∫0Tf(t)dt (2)

Write the general expression for Fourier series coefficient an.

an=2T∫0Tf(t)cosnω0tdt (3)

Write the general expression for Fourier series coefficient bn.

bn=2T∫0Tf(t)sinnω0tdt (4)

Write the expression to calculate the fundamental angular frequency.

ω0=2πT=2πf0 (5)

Here,

T is the period of the function.

Calculation:

In the given Figure 17.31, the time period is T=0.4.

The function v(t) for the given waveform is,

v(t)={Vmcos5πt, −0.1≤t≤0.10, 0.1≤t≤0.3 (6)

Substitute 0.4 for T in equation (5) to find ω0.

ω0=2π0.4

ω0=5π (7)

Applying equation (6) in equation (2) to find a0 as follows,

a0=10.4∫00.4v(t)dt=10.4[∫−0.10.1Vmcos5πtdt+∫0.10.3(0)dt+]=Vm0.4[sin5πt5π]−0.10.1=Vm0.4[sin5π(0.1)5π−sin5π(−0.1)5π]=Vm0.4[1+15π]

Simplify the above equation as follows,

a0=Vmπ

For half wave symmetry and even symmetry,

For all values of ‘n’, bn=0.

Applying equation (6) in equation (3) to find the value of coefficient an.

an=20.4∫00.4v(t)cosnω0tdt

an=2Vm0.4[∫−0.10.1cos(5πt)cos(5πnt)dt] {∵ω0=5π} (8)

Consider the function,

x=∫cos(5πt)cos(5πnt)dt

Consider,

u=5πt

On differentiating the above expression,

dudt=5πdt=du5π

Equation (8) will be follows,

x=15π∫cos(u)cos(nu)du (9)

In the above equation, consider,

y=∫cos(u)cos(nu)du=∫cos(nu+u)+cos(nu−u)2du {∵cos(x)cos(y)=12[cos(y+x)+cos(y−x)]}=∫cos((n+1)u)+cos((n−1)u)2du

By applying linearity,

y=12∫cos((n+1)u)du+12∫cos((n−1)u)du (10)

In equation (10),

consider,

m=∫cos((n+1)u)du (11)

Let,

v=(n+1)udvdu=(n+1)du=dvn+1

Equation (11) will be as follows,

m=1n+1∫cos(v)dv=sin(v)n+1=sin((n+1)u)n+1 {∵v=(n+1)u}

Similarly, in equation (10),

consider,

l=∫cos((n−1)u)du (12)

Let,

v=(n−1)udvdu=(n−1)du=dvn−1

Equation (12) will be as follows,

l=1n−1∫cos(v)dv=sin(v)n−1=sin((n−1)u)n−1 v=(n−1)u

Substitute the values of m and l in equation (10) as follows,

y=12[sin((n+1)u)n+1+sin((n−1)u)n−1]=sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)

Substitute the value of y in equation (9) as follows,

x=15π[sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)]=sin((n+1)u)10π(n+1)+sin((n−1)u)10π(n−1)=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1) {∵u=5πt}

Therefore,

∫cos(5πt)cos(5πnt)dt=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1)=(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)

On applying the limits,

∫−0.10.1cos(5πt)cos(5πnt)dt=[(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)]−0.10.1=[(n−1)sin(5π(n+1)(0.1))+(n+1)sin(5π(n−1)(0.1))10π(n2−1)]−[(n−1)sin(5π(n+1)(−0.1))+(n+1)sin(5π(n−1)(−0.1))10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]−[−(n−1)sin(nπ+π2)−(n+1)sin(nπ−π2)10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]+ [(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)]10π(n2−1)=2[(n−1)sin(nπ2+π2)+(n+1)sin(nπ2−π2)]10π(n2−1)=2[(n−1)cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1) {∵sin(90+θ)=cosθ,sin(−θ)=−sinθ}=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1)

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(nπ2)]10π(n2−1) {∵cos(−θ)=cosθ}=2[ncos(nπ2)−cos(nπ2)−ncos(nπ2)−cos(nπ2)]10π(n2−1)=2[−2cos(nπ2)]10π(n2−1)=−2cos(nπ2)5π(n2−1)

Substitute the value of ∫−0.10.1cos(5πt)cos(5πnt)dt in equation (8) as follows,

an=2Vm0.4[−2cos(nπ2)5π(n2−1)] =−2Vmcos(nπ2)π(n2−1)

an=2Vmπcos(nπ2)(1−n2) (n≠1)

Converting the equation (1) which is in angular frequency into frequency.

v(t)=a0+∑n=1∞(ancosnf0t+bnsinnf0t) (13)

Substitute the value of a0, an, and bn in equation (13) as follows,

v(t)=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(5π2π)t+0) {∵ f0=ω02π, ω0=5π}=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(52)t)

By considering Vm=1 V, the above equation will be as follows,

v(t)=1π+∑n=1∞((2π)(cos(nπ2)1−n2)cosn(52)t) (14)

For n=0, the equation (14) will be as follows,

v(t)=1π

For n=2, the equation (14) will be as follows,

v(t)=1π+(2π)(cos(2π2)1−(2)2)cos(2)(52)t=1π+(2π)(−1−3)cos(5)t=1π+(2π)(−1−3)cos(5)t=1π+0.2cos5t

The sketch for the line spectrum is shown in Figure 1.

Engineering Circuit Analysis, Chapter 17, Problem 15E

Conclusion:

Thus, the line spectrum for the given waveform is sketched as shown in Figure 1.

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Answer 4

Question

Chapter 17, Problem 15E

To determine

Sketch the line spectrum for the waveform shown in Figure 17.31.

Expert Solution & Answer

Answer to Problem 15E

The line spectrum for the given waveform is sketched as shown in Figure 1.

Explanation of Solution

Given data:

Refer to Figure 17.31 in the textbook.

Formula used:

Write the general expression for Fourier series expansion.

f(t)=a0+∑n=1∞(ancosnω0t+bnsinnω0t) (1)

Write the general expression for Fourier series coefficient a0.

a0=1T∫0Tf(t)dt (2)

Write the general expression for Fourier series coefficient an.

an=2T∫0Tf(t)cosnω0tdt (3)

Write the general expression for Fourier series coefficient bn.

bn=2T∫0Tf(t)sinnω0tdt (4)

Write the expression to calculate the fundamental angular frequency.

ω0=2πT=2πf0 (5)

Here,

T is the period of the function.

Calculation:

In the given Figure 17.31, the time period is T=0.4.

The function v(t) for the given waveform is,

v(t)={Vmcos5πt, −0.1≤t≤0.10, 0.1≤t≤0.3 (6)

Substitute 0.4 for T in equation (5) to find ω0.

ω0=2π0.4

ω0=5π (7)

Applying equation (6) in equation (2) to find a0 as follows,

a0=10.4∫00.4v(t)dt=10.4[∫−0.10.1Vmcos5πtdt+∫0.10.3(0)dt+]=Vm0.4[sin5πt5π]−0.10.1=Vm0.4[sin5π(0.1)5π−sin5π(−0.1)5π]=Vm0.4[1+15π]

Simplify the above equation as follows,

a0=Vmπ

For half wave symmetry and even symmetry,

For all values of ‘n’, bn=0.

Applying equation (6) in equation (3) to find the value of coefficient an.

an=20.4∫00.4v(t)cosnω0tdt

an=2Vm0.4[∫−0.10.1cos(5πt)cos(5πnt)dt] {∵ω0=5π} (8)

Consider the function,

x=∫cos(5πt)cos(5πnt)dt

Consider,

u=5πt

On differentiating the above expression,

dudt=5πdt=du5π

Equation (8) will be follows,

x=15π∫cos(u)cos(nu)du (9)

In the above equation, consider,

y=∫cos(u)cos(nu)du=∫cos(nu+u)+cos(nu−u)2du {∵cos(x)cos(y)=12[cos(y+x)+cos(y−x)]}=∫cos((n+1)u)+cos((n−1)u)2du

By applying linearity,

y=12∫cos((n+1)u)du+12∫cos((n−1)u)du (10)

In equation (10),

consider,

m=∫cos((n+1)u)du (11)

Let,

v=(n+1)udvdu=(n+1)du=dvn+1

Equation (11) will be as follows,

m=1n+1∫cos(v)dv=sin(v)n+1=sin((n+1)u)n+1 {∵v=(n+1)u}

Similarly, in equation (10),

consider,

l=∫cos((n−1)u)du (12)

Let,

v=(n−1)udvdu=(n−1)du=dvn−1

Equation (12) will be as follows,

l=1n−1∫cos(v)dv=sin(v)n−1=sin((n−1)u)n−1 v=(n−1)u

Substitute the values of m and l in equation (10) as follows,

y=12[sin((n+1)u)n+1+sin((n−1)u)n−1]=sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)

Substitute the value of y in equation (9) as follows,

x=15π[sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)]=sin((n+1)u)10π(n+1)+sin((n−1)u)10π(n−1)=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1) {∵u=5πt}

Therefore,

∫cos(5πt)cos(5πnt)dt=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1)=(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)

On applying the limits,

∫−0.10.1cos(5πt)cos(5πnt)dt=[(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)]−0.10.1=[(n−1)sin(5π(n+1)(0.1))+(n+1)sin(5π(n−1)(0.1))10π(n2−1)]−[(n−1)sin(5π(n+1)(−0.1))+(n+1)sin(5π(n−1)(−0.1))10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]−[−(n−1)sin(nπ+π2)−(n+1)sin(nπ−π2)10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]+ [(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)]10π(n2−1)=2[(n−1)sin(nπ2+π2)+(n+1)sin(nπ2−π2)]10π(n2−1)=2[(n−1)cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1) {∵sin(90+θ)=cosθ,sin(−θ)=−sinθ}=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1)

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(nπ2)]10π(n2−1) {∵cos(−θ)=cosθ}=2[ncos(nπ2)−cos(nπ2)−ncos(nπ2)−cos(nπ2)]10π(n2−1)=2[−2cos(nπ2)]10π(n2−1)=−2cos(nπ2)5π(n2−1)

Substitute the value of ∫−0.10.1cos(5πt)cos(5πnt)dt in equation (8) as follows,

an=2Vm0.4[−2cos(nπ2)5π(n2−1)] =−2Vmcos(nπ2)π(n2−1)

an=2Vmπcos(nπ2)(1−n2) (n≠1)

Converting the equation (1) which is in angular frequency into frequency.

v(t)=a0+∑n=1∞(ancosnf0t+bnsinnf0t) (13)

Substitute the value of a0, an, and bn in equation (13) as follows,

v(t)=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(5π2π)t+0) {∵ f0=ω02π, ω0=5π}=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(52)t)

By considering Vm=1 V, the above equation will be as follows,

v(t)=1π+∑n=1∞((2π)(cos(nπ2)1−n2)cosn(52)t) (14)

For n=0, the equation (14) will be as follows,

v(t)=1π

For n=2, the equation (14) will be as follows,

v(t)=1π+(2π)(cos(2π2)1−(2)2)cos(2)(52)t=1π+(2π)(−1−3)cos(5)t=1π+(2π)(−1−3)cos(5)t=1π+0.2cos5t

The sketch for the line spectrum is shown in Figure 1.

Engineering Circuit Analysis, Chapter 17, Problem 15E

Conclusion:

Thus, the line spectrum for the given waveform is sketched as shown in Figure 1.

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Answer 5

Chapter 17, Problem 15E

To determine

Sketch the line spectrum for the waveform shown in Figure 17.31.

Expert Solution & Answer

Answer to Problem 15E

The line spectrum for the given waveform is sketched as shown in Figure 1.

Explanation of Solution

Given data:

Refer to Figure 17.31 in the textbook.

Formula used:

Write the general expression for Fourier series expansion.

f(t)=a0+∑n=1∞(ancosnω0t+bnsinnω0t) (1)

Write the general expression for Fourier series coefficient a0.

a0=1T∫0Tf(t)dt (2)

Write the general expression for Fourier series coefficient an.

an=2T∫0Tf(t)cosnω0tdt (3)

Write the general expression for Fourier series coefficient bn.

bn=2T∫0Tf(t)sinnω0tdt (4)

Write the expression to calculate the fundamental angular frequency.

ω0=2πT=2πf0 (5)

Here,

T is the period of the function.

Calculation:

In the given Figure 17.31, the time period is T=0.4.

The function v(t) for the given waveform is,

v(t)={Vmcos5πt, −0.1≤t≤0.10, 0.1≤t≤0.3 (6)

Substitute 0.4 for T in equation (5) to find ω0.

ω0=2π0.4

ω0=5π (7)

Applying equation (6) in equation (2) to find a0 as follows,

a0=10.4∫00.4v(t)dt=10.4[∫−0.10.1Vmcos5πtdt+∫0.10.3(0)dt+]=Vm0.4[sin5πt5π]−0.10.1=Vm0.4[sin5π(0.1)5π−sin5π(−0.1)5π]=Vm0.4[1+15π]

Simplify the above equation as follows,

a0=Vmπ

For half wave symmetry and even symmetry,

For all values of ‘n’, bn=0.

Applying equation (6) in equation (3) to find the value of coefficient an.

an=20.4∫00.4v(t)cosnω0tdt

an=2Vm0.4[∫−0.10.1cos(5πt)cos(5πnt)dt] {∵ω0=5π} (8)

Consider the function,

x=∫cos(5πt)cos(5πnt)dt

Consider,

u=5πt

On differentiating the above expression,

dudt=5πdt=du5π

Equation (8) will be follows,

x=15π∫cos(u)cos(nu)du (9)

In the above equation, consider,

y=∫cos(u)cos(nu)du=∫cos(nu+u)+cos(nu−u)2du {∵cos(x)cos(y)=12[cos(y+x)+cos(y−x)]}=∫cos((n+1)u)+cos((n−1)u)2du

By applying linearity,

y=12∫cos((n+1)u)du+12∫cos((n−1)u)du (10)

In equation (10),

consider,

m=∫cos((n+1)u)du (11)

Let,

v=(n+1)udvdu=(n+1)du=dvn+1

Equation (11) will be as follows,

m=1n+1∫cos(v)dv=sin(v)n+1=sin((n+1)u)n+1 {∵v=(n+1)u}

Similarly, in equation (10),

consider,

l=∫cos((n−1)u)du (12)

Let,

v=(n−1)udvdu=(n−1)du=dvn−1

Equation (12) will be as follows,

l=1n−1∫cos(v)dv=sin(v)n−1=sin((n−1)u)n−1 v=(n−1)u

Substitute the values of m and l in equation (10) as follows,

y=12[sin((n+1)u)n+1+sin((n−1)u)n−1]=sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)

Substitute the value of y in equation (9) as follows,

x=15π[sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)]=sin((n+1)u)10π(n+1)+sin((n−1)u)10π(n−1)=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1) {∵u=5πt}

Therefore,

∫cos(5πt)cos(5πnt)dt=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1)=(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)

On applying the limits,

∫−0.10.1cos(5πt)cos(5πnt)dt=[(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)]−0.10.1=[(n−1)sin(5π(n+1)(0.1))+(n+1)sin(5π(n−1)(0.1))10π(n2−1)]−[(n−1)sin(5π(n+1)(−0.1))+(n+1)sin(5π(n−1)(−0.1))10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]−[−(n−1)sin(nπ+π2)−(n+1)sin(nπ−π2)10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]+ [(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)]10π(n2−1)=2[(n−1)sin(nπ2+π2)+(n+1)sin(nπ2−π2)]10π(n2−1)=2[(n−1)cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1) {∵sin(90+θ)=cosθ,sin(−θ)=−sinθ}=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1)

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(nπ2)]10π(n2−1) {∵cos(−θ)=cosθ}=2[ncos(nπ2)−cos(nπ2)−ncos(nπ2)−cos(nπ2)]10π(n2−1)=2[−2cos(nπ2)]10π(n2−1)=−2cos(nπ2)5π(n2−1)

Substitute the value of ∫−0.10.1cos(5πt)cos(5πnt)dt in equation (8) as follows,

an=2Vm0.4[−2cos(nπ2)5π(n2−1)] =−2Vmcos(nπ2)π(n2−1)

an=2Vmπcos(nπ2)(1−n2) (n≠1)

Converting the equation (1) which is in angular frequency into frequency.

v(t)=a0+∑n=1∞(ancosnf0t+bnsinnf0t) (13)

Substitute the value of a0, an, and bn in equation (13) as follows,

v(t)=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(5π2π)t+0) {∵ f0=ω02π, ω0=5π}=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(52)t)

By considering Vm=1 V, the above equation will be as follows,

v(t)=1π+∑n=1∞((2π)(cos(nπ2)1−n2)cosn(52)t) (14)

For n=0, the equation (14) will be as follows,

v(t)=1π

For n=2, the equation (14) will be as follows,

v(t)=1π+(2π)(cos(2π2)1−(2)2)cos(2)(52)t=1π+(2π)(−1−3)cos(5)t=1π+(2π)(−1−3)cos(5)t=1π+0.2cos5t

The sketch for the line spectrum is shown in Figure 1.

Engineering Circuit Analysis, Chapter 17, Problem 15E

Conclusion:

Thus, the line spectrum for the given waveform is sketched as shown in Figure 1.

Answer 6

Chapter 17, Problem 15E

To determine

Sketch the line spectrum for the waveform shown in Figure 17.31.

Expert Solution & Answer

Answer to Problem 15E

The line spectrum for the given waveform is sketched as shown in Figure 1.

Explanation of Solution

Given data:

Refer to Figure 17.31 in the textbook.

Formula used:

Write the general expression for Fourier series expansion.

f(t)=a0+∑n=1∞(ancosnω0t+bnsinnω0t) (1)

Write the general expression for Fourier series coefficient a0.

a0=1T∫0Tf(t)dt (2)

Write the general expression for Fourier series coefficient an.

an=2T∫0Tf(t)cosnω0tdt (3)

Write the general expression for Fourier series coefficient bn.

bn=2T∫0Tf(t)sinnω0tdt (4)

Write the expression to calculate the fundamental angular frequency.

ω0=2πT=2πf0 (5)

Here,

T is the period of the function.

Calculation:

In the given Figure 17.31, the time period is T=0.4.

The function v(t) for the given waveform is,

v(t)={Vmcos5πt, −0.1≤t≤0.10, 0.1≤t≤0.3 (6)

Substitute 0.4 for T in equation (5) to find ω0.

ω0=2π0.4

ω0=5π (7)

Applying equation (6) in equation (2) to find a0 as follows,

a0=10.4∫00.4v(t)dt=10.4[∫−0.10.1Vmcos5πtdt+∫0.10.3(0)dt+]=Vm0.4[sin5πt5π]−0.10.1=Vm0.4[sin5π(0.1)5π−sin5π(−0.1)5π]=Vm0.4[1+15π]

Simplify the above equation as follows,

a0=Vmπ

For half wave symmetry and even symmetry,

For all values of ‘n’, bn=0.

Applying equation (6) in equation (3) to find the value of coefficient an.

an=20.4∫00.4v(t)cosnω0tdt

an=2Vm0.4[∫−0.10.1cos(5πt)cos(5πnt)dt] {∵ω0=5π} (8)

Consider the function,

x=∫cos(5πt)cos(5πnt)dt

Consider,

u=5πt

On differentiating the above expression,

dudt=5πdt=du5π

Equation (8) will be follows,

x=15π∫cos(u)cos(nu)du (9)

In the above equation, consider,

y=∫cos(u)cos(nu)du=∫cos(nu+u)+cos(nu−u)2du {∵cos(x)cos(y)=12[cos(y+x)+cos(y−x)]}=∫cos((n+1)u)+cos((n−1)u)2du

By applying linearity,

y=12∫cos((n+1)u)du+12∫cos((n−1)u)du (10)

In equation (10),

consider,

m=∫cos((n+1)u)du (11)

Let,

v=(n+1)udvdu=(n+1)du=dvn+1

Equation (11) will be as follows,

m=1n+1∫cos(v)dv=sin(v)n+1=sin((n+1)u)n+1 {∵v=(n+1)u}

Similarly, in equation (10),

consider,

l=∫cos((n−1)u)du (12)

Let,

v=(n−1)udvdu=(n−1)du=dvn−1

Equation (12) will be as follows,

l=1n−1∫cos(v)dv=sin(v)n−1=sin((n−1)u)n−1 v=(n−1)u

Substitute the values of m and l in equation (10) as follows,

y=12[sin((n+1)u)n+1+sin((n−1)u)n−1]=sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)

Substitute the value of y in equation (9) as follows,

x=15π[sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)]=sin((n+1)u)10π(n+1)+sin((n−1)u)10π(n−1)=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1) {∵u=5πt}

Therefore,

∫cos(5πt)cos(5πnt)dt=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1)=(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)

On applying the limits,

∫−0.10.1cos(5πt)cos(5πnt)dt=[(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)]−0.10.1=[(n−1)sin(5π(n+1)(0.1))+(n+1)sin(5π(n−1)(0.1))10π(n2−1)]−[(n−1)sin(5π(n+1)(−0.1))+(n+1)sin(5π(n−1)(−0.1))10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]−[−(n−1)sin(nπ+π2)−(n+1)sin(nπ−π2)10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]+ [(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)]10π(n2−1)=2[(n−1)sin(nπ2+π2)+(n+1)sin(nπ2−π2)]10π(n2−1)=2[(n−1)cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1) {∵sin(90+θ)=cosθ,sin(−θ)=−sinθ}=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1)

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(nπ2)]10π(n2−1) {∵cos(−θ)=cosθ}=2[ncos(nπ2)−cos(nπ2)−ncos(nπ2)−cos(nπ2)]10π(n2−1)=2[−2cos(nπ2)]10π(n2−1)=−2cos(nπ2)5π(n2−1)

Substitute the value of ∫−0.10.1cos(5πt)cos(5πnt)dt in equation (8) as follows,

an=2Vm0.4[−2cos(nπ2)5π(n2−1)] =−2Vmcos(nπ2)π(n2−1)

an=2Vmπcos(nπ2)(1−n2) (n≠1)

Converting the equation (1) which is in angular frequency into frequency.

v(t)=a0+∑n=1∞(ancosnf0t+bnsinnf0t) (13)

Substitute the value of a0, an, and bn in equation (13) as follows,

v(t)=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(5π2π)t+0) {∵ f0=ω02π, ω0=5π}=Vmπ+∑n=1∞((2Vmπ)(cos(nπ2)1−n2)cosn(52)t)

By considering Vm=1 V, the above equation will be as follows,

v(t)=1π+∑n=1∞((2π)(cos(nπ2)1−n2)cosn(52)t) (14)

For n=0, the equation (14) will be as follows,

v(t)=1π

For n=2, the equation (14) will be as follows,

v(t)=1π+(2π)(cos(2π2)1−(2)2)cos(2)(52)t=1π+(2π)(−1−3)cos(5)t=1π+(2π)(−1−3)cos(5)t=1π+0.2cos5t

The sketch for the line spectrum is shown in Figure 1.

Engineering Circuit Analysis, Chapter 17, Problem 15E

Conclusion:

Thus, the line spectrum for the given waveform is sketched as shown in Figure 1.

Answer 7

Chapter 17, Problem 15E

To determine

Sketch the line spectrum for the waveform shown in Figure 17.31.

Answer 8

Expert Solution & Answer

Answer to Problem 15E

The line spectrum for the given waveform is sketched as shown in Figure 1.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given data:

Refer to Figure 17.31 in the textbook.

Formula used:

Write the general expression for Fourier series expansion.

f(t)=a0+∑n=1∞(ancosnω0t+bnsinnω0t) (1)

Write the general expression for Fourier series coefficient a0.

a0=1T∫0Tf(t)dt (2)

Write the general expression for Fourier series coefficient an.

an=2T∫0Tf(t)cosnω0tdt (3)

Write the general expression for Fourier series coefficient bn.

bn=2T∫0Tf(t)sinnω0tdt (4)

Write the expression to calculate the fundamental angular frequency.

ω0=2πT=2πf0 (5)

Here,

T is the period of the function.

Calculation:

In the given Figure 17.31, the time period is T=0.4.

The function v(t) for the given waveform is,

v(t)={Vmcos5πt, −0.1≤t≤0.10, 0.1≤t≤0.3 (6)

Substitute 0.4 for T in equation (5) to find ω0.

ω0=2π0.4

ω0=5π (7)

Applying equation (6) in equation (2) to find a0 as follows,

a0=10.4∫00.4v(t)dt=10.4[∫−0.10.1Vmcos5πtdt+∫0.10.3(0)dt+]=Vm0.4[sin5πt5π]−0.10.1=Vm0.4[sin5π(0.1)5π−sin5π(−0.1)5π]=Vm0.4[1+15π]

Simplify the above equation as follows,

a0=Vmπ

For half wave symmetry and even symmetry,

For all values of ‘n’, bn=0.

Applying equation (6) in equation (3) to find the value of coefficient an.

an=20.4∫00.4v(t)cosnω0tdt

an=2Vm0.4[∫−0.10.1cos(5πt)cos(5πnt)dt] {∵ω0=5π} (8)

Consider the function,

x=∫cos(5πt)cos(5πnt)dt

Consider,

u=5πt

On differentiating the above expression,

dudt=5πdt=du5π

Equation (8) will be follows,

x=15π∫cos(u)cos(nu)du (9)

In the above equation, consider,

y=∫cos(u)cos(nu)du=∫cos(nu+u)+cos(nu−u)2du {∵cos(x)cos(y)=12[cos(y+x)+cos(y−x)]}=∫cos((n+1)u)+cos((n−1)u)2du

By applying linearity,

y=12∫cos((n+1)u)du+12∫cos((n−1)u)du (10)

In equation (10),

consider,

m=∫cos((n+1)u)du (11)

Let,

v=(n+1)udvdu=(n+1)du=dvn+1

Equation (11) will be as follows,

m=1n+1∫cos(v)dv=sin(v)n+1=sin((n+1)u)n+1 {∵v=(n+1)u}

Similarly, in equation (10),

consider,

l=∫cos((n−1)u)du (12)

Let,

v=(n−1)udvdu=(n−1)du=dvn−1

Equation (12) will be as follows,

l=1n−1∫cos(v)dv=sin(v)n−1=sin((n−1)u)n−1 v=(n−1)u

Substitute the values of m and l in equation (10) as follows,

y=12[sin((n+1)u)n+1+sin((n−1)u)n−1]=sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)

Substitute the value of y in equation (9) as follows,

x=15π[sin((n+1)u)2(n+1)+sin((n−1)u)2(n−1)]=sin((n+1)u)10π(n+1)+sin((n−1)u)10π(n−1)=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1) {∵u=5πt}

Therefore,

∫cos(5πt)cos(5πnt)dt=sin(5π(n+1)t)10π(n+1)+sin(5π(n−1)t)10π(n−1)=(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)

On applying the limits,

∫−0.10.1cos(5πt)cos(5πnt)dt=[(n−1)sin(5π(n+1)t)+(n+1)sin(5π(n−1)t)10π(n2−1)]−0.10.1=[(n−1)sin(5π(n+1)(0.1))+(n+1)sin(5π(n−1)(0.1))10π(n2−1)]−[(n−1)sin(5π(n+1)(−0.1))+(n+1)sin(5π(n−1)(−0.1))10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]−[−(n−1)sin(nπ+π2)−(n+1)sin(nπ−π2)10π(n2−1)]=[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]+ [(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)10π(n2−1)]

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[(n−1)sin(nπ+π2)+(n+1)sin(nπ−π2)]10π(n2−1)=2[(n−1)sin(nπ2+π2)+(n+1)sin(nπ2−π2)]10π(n2−1)=2[(n−1)cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1) {∵sin(90+θ)=cosθ,sin(−θ)=−sinθ}=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(−nπ2)]10π(n2−1)

Simplify the equation as follows,

∫−0.10.1cos(5πt)cos(5πnt)dt=2[ncos(nπ2)−cos(nπ2)−(n+1)cos(nπ2)]10π(n2−1) {∵cos(−θ)=cosθ}=2[ncos(nπ2)−cos(nπ2)−ncos(nπ2)−cos(nπ2)]10π(n2−1)=2[−2cos(nπ2)]10π(n2−1)=−2cos(nπ2)5π(n2−1)