(a) What mode (m-value) is this?

Question

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Answer 1

Question

Chapter 17, Problem 1CQ

To determine

(a)

What mode (m-value) is this?

Expert Solution

Answer to Problem 1CQ

Solution: 4 antinodes

Explanation of Solution

Given:

A standing wave oscillating on a string at frequency f₀.

Formula used:

f=nv/2l

Where f is the natural frequency

n is the no. of antinodes

v is the velocity of wave

l is the length of the string

Let m-value be n then:

From the figure we can see that there 4 anti-nodes.

To determine

(b)

How many antinodes will there be if the frequency is doubled to 2f₀

Expert Solution

Answer to Problem 1CQ

Solution:

8 antinodes

Explanation of Solution

Calculation:

Suppose L be the length of the string.

L=nλ/2

We have n = 4,

so:

λ=L/2

Let f₀ be the frequency.

v=f0λ = f0×L/2 = f0L/2

When frequency is doubled then f0 becomes 2 f0:

Using f=nv/2l, we get:

2 f0 = nv/2L=(n×f0×L)/(2×2×L)

From above calculation we will get:

n = 8

Conclusion:

Using the f=nv/2l, number of nodes and antinodes can be calculated when other things are provided.

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Answer 2

Question

Chapter 17, Problem 1CQ

To determine

(a)

What mode (m-value) is this?

Expert Solution

Answer to Problem 1CQ

Solution: 4 antinodes

Explanation of Solution

Given:

A standing wave oscillating on a string at frequency f₀.

Formula used:

f=nv/2l

Where f is the natural frequency

n is the no. of antinodes

v is the velocity of wave

l is the length of the string

Let m-value be n then:

From the figure we can see that there 4 anti-nodes.

To determine

(b)

How many antinodes will there be if the frequency is doubled to 2f₀

Expert Solution

Answer to Problem 1CQ

Solution:

8 antinodes

Explanation of Solution

Calculation:

Suppose L be the length of the string.

L=nλ/2

We have n = 4,

so:

λ=L/2

Let f₀ be the frequency.

v=f0λ = f0×L/2 = f0L/2

When frequency is doubled then f0 becomes 2 f0:

Using f=nv/2l, we get:

2 f0 = nv/2L=(n×f0×L)/(2×2×L)

From above calculation we will get:

n = 8

Conclusion:

Using the f=nv/2l, number of nodes and antinodes can be calculated when other things are provided.

Want to see more full solutions like this?

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

Answer 3

Question

Chapter 17, Problem 1CQ

To determine

(a)

What mode (m-value) is this?

Expert Solution

Answer to Problem 1CQ

Solution: 4 antinodes

Explanation of Solution

Given:

A standing wave oscillating on a string at frequency f₀.

Formula used:

f=nv/2l

Where f is the natural frequency

n is the no. of antinodes

v is the velocity of wave

l is the length of the string

Let m-value be n then:

From the figure we can see that there 4 anti-nodes.

To determine

(b)

How many antinodes will there be if the frequency is doubled to 2f₀

Expert Solution

Answer to Problem 1CQ

Solution:

8 antinodes

Explanation of Solution

Calculation:

Suppose L be the length of the string.

L=nλ/2

We have n = 4,

so:

λ=L/2

Let f₀ be the frequency.

v=f0λ = f0×L/2 = f0L/2

When frequency is doubled then f0 becomes 2 f0:

Using f=nv/2l, we get:

2 f0 = nv/2L=(n×f0×L)/(2×2×L)

From above calculation we will get:

n = 8

Conclusion:

Using the f=nv/2l, number of nodes and antinodes can be calculated when other things are provided.

Want to see more full solutions like this?

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

Answer 4

Question

Chapter 17, Problem 1CQ

To determine

(a)

What mode (m-value) is this?

Expert Solution

Answer to Problem 1CQ

Solution: 4 antinodes

Explanation of Solution

Given:

A standing wave oscillating on a string at frequency f₀.

Formula used:

f=nv/2l

Where f is the natural frequency

n is the no. of antinodes

v is the velocity of wave

l is the length of the string

Let m-value be n then:

From the figure we can see that there 4 anti-nodes.

To determine

(b)

How many antinodes will there be if the frequency is doubled to 2f₀

Expert Solution

Answer to Problem 1CQ

Solution:

8 antinodes

Explanation of Solution

Calculation:

Suppose L be the length of the string.

L=nλ/2

We have n = 4,

so:

λ=L/2

Let f₀ be the frequency.

v=f0λ = f0×L/2 = f0L/2

When frequency is doubled then f0 becomes 2 f0:

Using f=nv/2l, we get:

2 f0 = nv/2L=(n×f0×L)/(2×2×L)

From above calculation we will get:

n = 8

Conclusion:

Using the f=nv/2l, number of nodes and antinodes can be calculated when other things are provided.

Want to see more full solutions like this?

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

Answer 5

Chapter 17, Problem 1CQ

To determine

(a)

What mode (m-value) is this?

Expert Solution

Answer to Problem 1CQ

Solution: 4 antinodes

Explanation of Solution

Given:

A standing wave oscillating on a string at frequency f₀.

Formula used:

f=nv/2l

Where f is the natural frequency

n is the no. of antinodes

v is the velocity of wave

l is the length of the string

Let m-value be n then:

From the figure we can see that there 4 anti-nodes.

To determine

(b)

How many antinodes will there be if the frequency is doubled to 2f₀

Expert Solution

Answer to Problem 1CQ

Solution:

8 antinodes

Explanation of Solution

Calculation:

Suppose L be the length of the string.

L=nλ/2

We have n = 4,

so:

λ=L/2

Let f₀ be the frequency.

v=f0λ = f0×L/2 = f0L/2

When frequency is doubled then f0 becomes 2 f0:

Using f=nv/2l, we get:

2 f0 = nv/2L=(n×f0×L)/(2×2×L)

From above calculation we will get:

n = 8

Conclusion:

Using the f=nv/2l, number of nodes and antinodes can be calculated when other things are provided.

Answer 6

Chapter 17, Problem 1CQ

To determine

(a)

What mode (m-value) is this?

Expert Solution

Answer to Problem 1CQ

Solution: 4 antinodes

Explanation of Solution

Given:

A standing wave oscillating on a string at frequency f₀.

Formula used:

f=nv/2l

Where f is the natural frequency

n is the no. of antinodes

v is the velocity of wave

l is the length of the string

Let m-value be n then:

From the figure we can see that there 4 anti-nodes.

Answer 7

Chapter 17, Problem 1CQ

To determine

(a)

What mode (m-value) is this?

Answer 8

Expert Solution

Answer to Problem 1CQ

Solution: 4 antinodes

Answer 9

Expert Solution

Answer 10

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given:

A standing wave oscillating on a string at frequency f₀.

Formula used:

f=nv/2l

Where f is the natural frequency

n is the no. of antinodes

v is the velocity of wave

l is the length of the string

Let m-value be n then:

From the figure we can see that there 4 anti-nodes.

Answer 13

To determine

(b)

How many antinodes will there be if the frequency is doubled to 2f₀

Expert Solution

Answer to Problem 1CQ

Solution:

8 antinodes

Explanation of Solution

Calculation:

Suppose L be the length of the string.

L=nλ/2

We have n = 4,

so:

λ=L/2

Let f₀ be the frequency.

v=f0λ = f0×L/2 = f0L/2

When frequency is doubled then f0 becomes 2 f0:

Using f=nv/2l, we get:

2 f0 = nv/2L=(n×f0×L)/(2×2×L)

From above calculation we will get:

n = 8

Conclusion:

Using the f=nv/2l, number of nodes and antinodes can be calculated when other things are provided.

Answer 14

To determine

(b)

How many antinodes will there be if the frequency is doubled to 2f₀

Answer 15

Expert Solution

Answer to Problem 1CQ

Solution:

8 antinodes

Answer 16

Expert Solution

Answer 17

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Calculation:

Suppose L be the length of the string.

L=nλ/2

We have n = 4,

so:

λ=L/2

Let f₀ be the frequency.

v=f0λ = f0×L/2 = f0L/2

When frequency is doubled then f0 becomes 2 f0:

Using f=nv/2l, we get:

2 f0 = nv/2L=(n×f0×L)/(2×2×L)

From above calculation we will get:

n = 8

Conclusion:

Using the f=nv/2l, number of nodes and antinodes can be calculated when other things are provided.

Answer 20

Ch. 17 - Prob. 1CQ Ch. 17 - If you take snapshots of a standing wave on a...Ch. 17 - Prob. 3CQ Ch. 17 - Prob. 4CQ Ch. 17 - Prob. 5CQ Ch. 17 - Prob. 6CQ Ch. 17 - Prob. 7CQ Ch. 17 - Prob. 8CQ Ch. 17 - Prob. 9CQ Ch. 17 - 10. A trumpet player hears 5 beats per second when...

(a) What mode (m-value) is this?

Concept explainers

Videos

(a)

What mode (m-value) is this?

Answer to Problem 1CQ

Explanation of Solution

(b)

How many antinodes will there be if the frequency is doubled to 2f₀

Answer to Problem 1CQ

Explanation of Solution

Want to see more full solutions like this?

Chapter 17 Solutions

(a) What mode (m-value) is this?

Concept explainers

Videos

(a) What mode (m-value) is this?

Answer to Problem 1CQ

Explanation of Solution

(b) How many antinodes will there be if the frequency is doubled to 2f0

Answer to Problem 1CQ

Explanation of Solution

Want to see more full solutions like this?

Chapter 17 Solutions

(a)

What mode (m-value) is this?

(b)

How many antinodes will there be if the frequency is doubled to 2f₀