Which of the following describe ϕ for the SHM of Fig. 15-20 a : (a) −π < ϕ < −π/2, (b) π < ϕ < 3 π/3, (c) −3 π/2 < ϕ < −π? Figure 15-20

Question

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Answer 1

Textbook Question

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Chapter 15, Problem 1Q

Which of the following describe ϕ for the SHM of Fig. 15-20a:

(a) −π < ϕ < −π/2,

(b) π < ϕ < 3 π/3,

(c) −3 π/2 < ϕ < −π?

Chapter 15, Problem 1Q, Which of the following describe for the SHM of Fig. 15-20a: a /2, b 3 /3, c 3 /2 ?

Figure 15-20

Definition Definition Special type of oscillation where the force of restoration is directly proportional to the displacement of the object from its mean or initial position. If an object is in motion such that the acceleration of the object is directly proportional to its displacement (which helps the moving object return to its resting position) then the object is said to undergo a simple harmonic motion. An object undergoing SHM always moves like a wave.

Expert Solution & Answer

To determine

To find:

The limits which describes ∅ for SHM.

Answer to Problem 1Q

Solution:

The limits which describes ∅ for the SHM are π<∅<3π2 and-π<∅<-π2.

Explanation of Solution

1) Concept:

We can use displacementof SHM to find the expression for x at t = 0.Then observing the graph, we can interpret the possible values of the phase angle.

2) Formulae:

Xt=Acos⁡(ωt+ ∅)

3) Given:

The graph of x vs t is given.

4) Calculations:

Limit which describes ∅ for SHM:

We know the equation of SHM

Xt=Acos⁡(ωt+ ∅)

Where A is the maximum displacement, ω is the angular velocity, t is time and ∅ is the phase difference.

At t = 0 we get,

X=Acos(∅)

From the graph, we can see that at t = 0 the value of X is negative, we know that the value of cos is negative in II and III quadrant.

So the limits are

π<∅<3π2 and-π<∅<-π2

Conclusion:

We can use the equation for displacement of SHM to find the phase angle of the oscillatory motion.

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Answer 2

Textbook Question

100%

Chapter 15, Problem 1Q

Which of the following describe ϕ for the SHM of Fig. 15-20a:

(a) −π < ϕ < −π/2,

(b) π < ϕ < 3 π/3,

(c) −3 π/2 < ϕ < −π?

Chapter 15, Problem 1Q, Which of the following describe for the SHM of Fig. 15-20a: a /2, b 3 /3, c 3 /2 ?

Figure 15-20

Definition Definition Special type of oscillation where the force of restoration is directly proportional to the displacement of the object from its mean or initial position. If an object is in motion such that the acceleration of the object is directly proportional to its displacement (which helps the moving object return to its resting position) then the object is said to undergo a simple harmonic motion. An object undergoing SHM always moves like a wave.

Expert Solution & Answer

To determine

To find:

The limits which describes ∅ for SHM.

Answer to Problem 1Q

Solution:

The limits which describes ∅ for the SHM are π<∅<3π2 and-π<∅<-π2.

Explanation of Solution

1) Concept:

We can use displacementof SHM to find the expression for x at t = 0.Then observing the graph, we can interpret the possible values of the phase angle.

2) Formulae:

Xt=Acos⁡(ωt+ ∅)

3) Given:

The graph of x vs t is given.

4) Calculations:

Limit which describes ∅ for SHM:

We know the equation of SHM

Xt=Acos⁡(ωt+ ∅)

Where A is the maximum displacement, ω is the angular velocity, t is time and ∅ is the phase difference.

At t = 0 we get,

X=Acos(∅)

From the graph, we can see that at t = 0 the value of X is negative, we know that the value of cos is negative in II and III quadrant.

So the limits are

π<∅<3π2 and-π<∅<-π2

Conclusion:

We can use the equation for displacement of SHM to find the phase angle of the oscillatory motion.

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Answer 3

Textbook Question

100%

Chapter 15, Problem 1Q

Which of the following describe ϕ for the SHM of Fig. 15-20a:

(a) −π < ϕ < −π/2,

(b) π < ϕ < 3 π/3,

(c) −3 π/2 < ϕ < −π?

Chapter 15, Problem 1Q, Which of the following describe for the SHM of Fig. 15-20a: a /2, b 3 /3, c 3 /2 ?

Figure 15-20

Definition Definition Special type of oscillation where the force of restoration is directly proportional to the displacement of the object from its mean or initial position. If an object is in motion such that the acceleration of the object is directly proportional to its displacement (which helps the moving object return to its resting position) then the object is said to undergo a simple harmonic motion. An object undergoing SHM always moves like a wave.

Expert Solution & Answer

To determine

To find:

The limits which describes ∅ for SHM.

Answer to Problem 1Q

Solution:

The limits which describes ∅ for the SHM are π<∅<3π2 and-π<∅<-π2.

Explanation of Solution

1) Concept:

We can use displacementof SHM to find the expression for x at t = 0.Then observing the graph, we can interpret the possible values of the phase angle.

2) Formulae:

Xt=Acos⁡(ωt+ ∅)

3) Given:

The graph of x vs t is given.

4) Calculations:

Limit which describes ∅ for SHM:

We know the equation of SHM

Xt=Acos⁡(ωt+ ∅)

Where A is the maximum displacement, ω is the angular velocity, t is time and ∅ is the phase difference.

At t = 0 we get,

X=Acos(∅)

From the graph, we can see that at t = 0 the value of X is negative, we know that the value of cos is negative in II and III quadrant.

So the limits are

π<∅<3π2 and-π<∅<-π2

Conclusion:

We can use the equation for displacement of SHM to find the phase angle of the oscillatory motion.

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Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Textbook Question

100%

Chapter 15, Problem 1Q

Which of the following describe ϕ for the SHM of Fig. 15-20a:

(a) −π < ϕ < −π/2,

(b) π < ϕ < 3 π/3,

(c) −3 π/2 < ϕ < −π?

Chapter 15, Problem 1Q, Which of the following describe for the SHM of Fig. 15-20a: a /2, b 3 /3, c 3 /2 ?

Figure 15-20

Definition Definition Special type of oscillation where the force of restoration is directly proportional to the displacement of the object from its mean or initial position. If an object is in motion such that the acceleration of the object is directly proportional to its displacement (which helps the moving object return to its resting position) then the object is said to undergo a simple harmonic motion. An object undergoing SHM always moves like a wave.

Expert Solution & Answer

To determine

To find:

The limits which describes ∅ for SHM.

Answer to Problem 1Q

Solution:

The limits which describes ∅ for the SHM are π<∅<3π2 and-π<∅<-π2.

Explanation of Solution

1) Concept:

We can use displacementof SHM to find the expression for x at t = 0.Then observing the graph, we can interpret the possible values of the phase angle.

2) Formulae:

Xt=Acos⁡(ωt+ ∅)

3) Given:

The graph of x vs t is given.

4) Calculations:

Limit which describes ∅ for SHM:

We know the equation of SHM

Xt=Acos⁡(ωt+ ∅)

Where A is the maximum displacement, ω is the angular velocity, t is time and ∅ is the phase difference.

At t = 0 we get,

X=Acos(∅)

From the graph, we can see that at t = 0 the value of X is negative, we know that the value of cos is negative in II and III quadrant.

So the limits are

π<∅<3π2 and-π<∅<-π2

Conclusion:

We can use the equation for displacement of SHM to find the phase angle of the oscillatory motion.

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Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Textbook Question

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Answer 6

Textbook Question

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Answer 7

Expert Solution & Answer

To determine

To find:

The limits which describes ∅ for SHM.

Answer to Problem 1Q

Solution:

The limits which describes ∅ for the SHM are π<∅<3π2 and-π<∅<-π2.

Explanation of Solution

1) Concept:

We can use displacementof SHM to find the expression for x at t = 0.Then observing the graph, we can interpret the possible values of the phase angle.

2) Formulae:

Xt=Acos⁡(ωt+ ∅)

3) Given:

The graph of x vs t is given.

4) Calculations:

Limit which describes ∅ for SHM:

We know the equation of SHM

Xt=Acos⁡(ωt+ ∅)

Where A is the maximum displacement, ω is the angular velocity, t is time and ∅ is the phase difference.

At t = 0 we get,

X=Acos(∅)

From the graph, we can see that at t = 0 the value of X is negative, we know that the value of cos is negative in II and III quadrant.

So the limits are

π<∅<3π2 and-π<∅<-π2

Conclusion:

We can use the equation for displacement of SHM to find the phase angle of the oscillatory motion.

Answer 8

Expert Solution & Answer

To determine

To find:

The limits which describes ∅ for SHM.

Answer to Problem 1Q

Solution:

The limits which describes ∅ for the SHM are π<∅<3π2 and-π<∅<-π2.

Explanation of Solution

1) Concept:

We can use displacementof SHM to find the expression for x at t = 0.Then observing the graph, we can interpret the possible values of the phase angle.

2) Formulae:

Xt=Acos⁡(ωt+ ∅)

3) Given:

The graph of x vs t is given.

4) Calculations:

Limit which describes ∅ for SHM:

We know the equation of SHM

Xt=Acos⁡(ωt+ ∅)

Where A is the maximum displacement, ω is the angular velocity, t is time and ∅ is the phase difference.

At t = 0 we get,

X=Acos(∅)

From the graph, we can see that at t = 0 the value of X is negative, we know that the value of cos is negative in II and III quadrant.

So the limits are

π<∅<3π2 and-π<∅<-π2

Conclusion:

We can use the equation for displacement of SHM to find the phase angle of the oscillatory motion.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

To find:

The limits which describes ∅ for SHM.

Answer 12

Answer to Problem 1Q

Solution:

The limits which describes ∅ for the SHM are π<∅<3π2 and-π<∅<-π2.

Answer 13

Explanation of Solution

1) Concept:

We can use displacementof SHM to find the expression for x at t = 0.Then observing the graph, we can interpret the possible values of the phase angle.

2) Formulae:

Xt=Acos⁡(ωt+ ∅)

3) Given:

The graph of x vs t is given.

4) Calculations:

Limit which describes ∅ for SHM:

We know the equation of SHM

Xt=Acos⁡(ωt+ ∅)

Where A is the maximum displacement, ω is the angular velocity, t is time and ∅ is the phase difference.

At t = 0 we get,

X=Acos(∅)

From the graph, we can see that at t = 0 the value of X is negative, we know that the value of cos is negative in II and III quadrant.