EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
9th Edition
ISBN: 8220100654428
Author: Jewett
Publisher: Cengage Learning US
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Concept explainers

Interference of sound
Seiche
A seiche is an oscillating standing wave in a body of water. The term seiche pronounced saysh) can be understood by the sloshing of water back and forth in a swimming pool. The same phenomenon happens on a much larger scale in vast bodies of water includ…
Question
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Chapter 16, Problem 16.13P

(a)

To determine

The frequency of the wave.

(a)

Expert Solution
Check Mark

Answer to Problem 16.13P

The frequency of the wave is 0.500Hz .

Explanation of Solution

Given info: The wavelength of wave is 2.00m , the amplitude is 0.100m . The speed of wave in string is 1.00m/s . The left end of wave is at origin at t=0 .

The formula to calculate frequency of wave is,

f=vλ

Here,

f is frequency of wave.

v is speed of wave.

λ is wavelength of wave.

Substitute 1.00m/s for v and 2.00m for λ in the above expression.

f=1.00m/s2.00m=0.500Hz

Conclusion:

Therefore, the frequency of the wave is 0.500Hz .

(b)

To determine

The angular frequency of the wave.

(b)

Expert Solution
Check Mark

Answer to Problem 16.13P

The angular frequency of the wave is 3.14rad/s .

Explanation of Solution

Given info: The wavelength of wave is 2.00m , the amplitude is 0.100m . The speed of wave in string is 1.00m/s . The left end of wave is at origin at t=0 .

The formula to calculate angular frequency of the wave is,

ω=2πf

Here,

ω is angular frequency of the wave.

Substitute 0.5Hz for f in the above expression.

ω=2π(0.5Hz)=πrad/s=3.14rad/s (1)

Conclusion:

Therefore, the angular frequency of the wave is 3.14rad/s .

(c)

To determine

The angular wave number of the wave.

(c)

Expert Solution
Check Mark

Answer to Problem 16.13P

The angular wave number of the wave is 3.14rad/m .

Explanation of Solution

Given info: The wavelength of wave is 2.00m , the amplitude is 0.100m . The speed of wave in string is 1.00m/s . The left end of wave is at origin at t=0 .

The formula to calculate angular wave number of the wave is,

k=2πλ

Here,

k is angular wave number.

Substitute 2.00m for λ in the above expression.

k=2π2.00m=πrad/m=3.14rad/m (2)

Conclusion:

Therefore, the angular wave number of the wave is 3.14rad/m .

(d)

To determine

The wave function of the wave.

(d)

Expert Solution
Check Mark

Answer to Problem 16.13P

The wave function of the wave is 0.100sin(πxπt) .

Explanation of Solution

Given info: The wavelength of wave is 2.00m , the amplitude is 0.100m . The speed of wave in string is 1.00m/s . The left end of wave is at origin at t=0 .

The formula of standard wave equation is,

y=Asin(kxωt)

Here,

A is amplitude of the wave.

k is angular wave number of the wave.

t is time period of wave.

Substitute 0.100m for A , πrad/m for k and πrad/s for ω in the above equation.

y=(0.100m)sin(πxπt) (3)

Conclusion:

Therefore, the function of the wave is 0.100sin(πxπt) .

(e)

To determine

The equation of motion for the left end of string.

(e)

Expert Solution
Check Mark

Answer to Problem 16.13P

The equation of motion for the left end of string is 0.100sin(πt) .

Explanation of Solution

Given info: The wavelength of wave is 2.00m , the amplitude is 0.100m . The speed of wave in string is 1.00m/s . The left end of wave is at origin at t=0 .

From equation (3),

y=(0.100m)sin(πxπt)

For the left end of string the position coordinate x of the wave is 0 .

Substitute 0 for x in the above equation.

y=(0.100m)sin(π(0)πt)=(0.100m)sin(πt)

Conclusion:

Therefore, the equation of motion for the left end of string is 0.100sin(πt) .

(f)

To determine

The point on the string x=1.50m to the right of left end.

(f)

Expert Solution
Check Mark

Answer to Problem 16.13P

The equation of motion for the left end of string is 0.100sin(4.71πt) .

Explanation of Solution

Given info: The wavelength of wave is 2.00m , the amplitude is 0.100m . The speed of wave in string is 1.00m/s . The left end of wave is at origin at t=0 .

From equation (3),

y=(0.100m)sin(πxπt)

For the point 1.50m to the right of the left end of the string:

Substitute 1.50m for x in the above expression.

y=(0.100m)sin(π(1.50m)πt)

Solve the above expression for y ,

y=(0.100m)sin(4.71πt)

Conclusion:

Therefore, the equation of motion for the left end of string is 0.100sin(4.71πt) .

(g)

To determine

The maximum speed of element of the string.

(g)

Expert Solution
Check Mark

Answer to Problem 16.13P

The maximum speed of element of string is 0.314m/s .

Explanation of Solution

Given info: The wavelength of wave is 2.00m , the amplitude is 0.100m . The speed of wave in string is 1.00m/s . The left end of wave is at origin at t=0 .

From equation (3), the position of the wave is,

y=(0.100m)sin(πxπt)

The change in position with respect to time gives the speed.

Differentiate above equation n with respect to time,

v=dydt

Here,

v is speed of the element of string.

Substitute (0.100m)sin(πxπt) for y in the above expression.

v=d((0.100m)sin(πxπt))dt

Solve the above expression for v ,

v=d((0.100m)sin(πxπt))dt=(0.100m)dsin(πxπt)dt+sin(πxπt)d(0.100m)dt=(0.100m)cos(πxπt)(π)+0

Substitute 3.14 for π in the above expression.

=(0.100m)cos((3.14)x(3.14)t)(3.14)+0=0.314mcos((3.14)x(3.14)t)

As the cosine wave varies from the positive of +1 to the negative of +1 . So the maximum speed of any element of string is 0.314m/s .

Conclusion:

Therefore, the maximum speed of element of string is 0.314m/s .

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Chapter 16 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

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