PHYSICS F/SCI.+ENGRS.,STAND.-W/ACCESS
PHYSICS F/SCI.+ENGRS.,STAND.-W/ACCESS
6th Edition
ISBN: 9781429206099
Author: Tipler
Publisher: MAC HIGHER
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Question
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Chapter 16, Problem 77P

(a)

To determine

Wave function of two waves.

(a)

Expert Solution
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Explanation of Solution

Given:

The wave function of standing wave is given as y(x,t)=(0.020)sin(12πx)cos(40πt) .

Introduction:

The superimposed traveling waves have same wave number and same angular frequency. However, the amplitude of superimposed waves is equal and half the amplitude of the standing wave.

Write expression for the wave function for the wave traveling in positive x-direction.

  y1(x,t)=(0.010m)sin[(π2m-1)x(40πs-1)t]

Write expression for the wave function for the wave traveling in negative x-direction.

  y2(x,t)=(0.010m)sin[(π2m-1)x+(40πs-1)t]

Conclusion:

Thus, the wave function for superimposed waves in positive and negative x-direction is given above.

(b)

To determine

The distance between nodes of the standing wave.

(b)

Expert Solution
Check Mark

Explanation of Solution

Given:

The wave function of standing wave is given as y(x,t)=(0.020)sin(12πx)cos(40πt) .

Formula used:

Write expression for wave number.

  k=2πλ

Rearrange above expression for λ .

  λ=2πk

Write expression for distance between adjacent nodes.

  d=12λ

Substitute 2πk for λ in above expression.

  d=πk........ (1)

Calculation:

Substitute π2 for k in equation (1).

  d=ππ2d=2m

Conclusion:

Thus, the distance between two waves is 2m .

(c)

To determine

The maximum speed of the rope at x=1.0m .

(c)

Expert Solution
Check Mark

Explanation of Solution

Given:

The wave function of standing wave is given as y(x,t)=(0.020)sin(12πx)cos(40πt) .

Formula used:

Write expression for standing wave.

  y(x,t)=(0.020)sin(12πx)cos(40πt)....... (1)

Calculation:

Differentiate equation (1) with respect to t .

  ddty(x,t)=ddt[(0.020)sin( 1 2πx)cos(40πt)]v(x,t)=(0.80π)sin(π2x)sin(40πt)

Substitute 1.0m for x in above expression.

  v(( 1.0m),t)=(0.80π)sin(π2( 1.0m))sin(40πt)v(( 1.0m),t)=(0.80πm/s)sin(40πs -1)tv(( 1.0m),t)=(2.5m/s)sin(40πs -1)t

Substitute vmax for v((1.0m),t) and 1 for sin(40πs-1)t in above expression.

  vmax=2.5m/s

Conclusion:

Thus, the maximum speed of the wave at x=1.0m is 2.5m/s .

(d)

To determine

The maximum acceleration of the rope at x=1.0m .

(d)

Expert Solution
Check Mark

Explanation of Solution

Given:

The wave function of standing wave is given as y(x,t)=(0.020)sin(12πx)cos(40πt) .

Formula used:

Write expression for standing wave.

  y(x,t)=(0.020)sin(12πx)cos(40πt)....... (1)

Calculation:

Differentiate equation (1) with respect to t .

  ddty(x,t)=ddt[(0.020)sin( 1 2πx)cos(40πt)]v(x,t)=(0.80π)sin(π2x)sin(40πt)

Differentiate above expression with respect to t .

  ddtv(x,t)=ddt[(0.80π)sin( π 2x)sin(40πt)]a(x,t)=±(32π2m/ s 2)cos(40πs -1)t

Substitute amax for a(x,t) and 1 for cos(40πs-1)t in above expression.

  amax=±316m/s2

Conclusion:

Thus, maximum acceleration at x=1.0m is ±316m/s2 .

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