Principles of Physics: A Calculus-Based Text
Principles of Physics: A Calculus-Based Text
5th Edition
ISBN: 9781133104261
Author: Raymond A. Serway, John W. Jewett
Publisher: Cengage Learning
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Chapter 13, Problem 62P

(a)

To determine

To show: The time interval for a transverse pulse to travel the length of the rope is Δt=2Lmg(M+m)M .

(a)

Expert Solution
Check Mark

Answer to Problem 62P

The time interval for a transverse pulse to travel the length of the rope is Δt=2Lmg(M+m)M .

Explanation of Solution

The free body diagram of the suspended object with rope is shown below.

Principles of Physics: A Calculus-Based Text, Chapter 13, Problem 62P

Figure (1)

From free body diagram, the tension is equal to the weight of the body.

T=Mg+mgLx

Here,

T is the tension in the rope.

m is the unit mass of the rope.

L is the length of the rope.

M is the mass of the suspended object.

g is the acceleration due to gravity.

Formula to calculate the linear mass density is,

μ=mL

Here,

μ is the linear mass density.

Formula to calculate the speed of the wave is,

v=Tμ (1)

Here, v is the speed of the wave.

Substitute mL for μ and Mg+mgLx for T in equation (1).

v=Mg+mgLxmL=g(MLm+x)

Formula to calculate the time taken to cover the smallest distance is,

v=dxdtdt=dxv (2)

Here,

dx is the smallest distance.

dt is the time taken to cover the smallest.

Substitute g(MLm+x) for v in equation (2).

dt=dxg(MLm+x)=1g(MLm+x)12dx (3)

Integrate the right hand side of equation (3) from 0 to L and left hand side from 0 to t for total time.

0tdt=0L1g(MLm+x)12dx(t0)=2g×Lm((M+m)M)Δt=2Lmg(M+mM)

Conclusion:

Therefore, the time interval for a transverse pulse to travel the length of the rope is Δt=2Lmg(M+m)M is verified.

(b)

To determine

To show:The expression in part (a) reduces to the result of Problem 48 when M=0 .

(b)

Expert Solution
Check Mark

Answer to Problem 62P

the expression in part (a) reduces to the result of Problem 48 when M=0 is 12Lg .

Explanation of Solution

The expression for the problem 48 is Δt=12Lg .

The given expression in part (a) for total time is,

Δt=2Lmg(M+m)M (4)

Substitute 0 for M in equation (4).

Δt=2Lmg(0+m)0=12Lg

Conclusion:

Therefore, the expression in part (a) reduces to the result of Problem 48 when M=0 is verified above.

(c)

To determine

To show:The expression in part (a) reduces to Δt=2mLMg for m<<M .

(c)

Expert Solution
Check Mark

Answer to Problem 62P

The expression in part (a) reduces to Δt=2mLMg for m<<M .

Explanation of Solution

The given expression in part (a) for total time is,

Δt=2Lmg(M+m)M=2Lmg[M12(1+mM)12M12]=2Lmg[M12(1+mM)121] (5)

Apply the binomial theorem in the equation (5).

Δt=2Lmg[M12(1+mM)121]=2Lmg[M12(1+m2M1)]=2LmgM(m2M)=mLMg

Conclusion:

Therefore, the expression in part (a) reduces to Δt=2mLMg for m<<M .

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Chapter 13 Solutions

Principles of Physics: A Calculus-Based Text

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