The ends of a stretched wire of length L...

The ends of a stretched wire of length `L` are fixed at `x = 0 and x = L`. In one experiment, the displacement of the wire is `y_(1) = A sin(pi//L) sin omegat` and energy is `E_(1)` and in another experiment its displacement is `y_(2) = A sin (2pix//L ) sin 2omegat` and energy is `E_(2)`. Then

`E_(2) = E_(1)`

`E_(2) = 2 E_(1)`

`E_(2) = 4 E_(1)`

`E_(2) = 16 E_(1)`

Text Solution

Verified by Experts

The correct Answer is:

Energy `prop ("amplitude")^(2) ("frequency")^(2)`
Amplitude (A) is same in both the cases, but frequency `2omega`, in the second case is two times the frequency `(omega)` in the first case,
`E_(2) = 4E_(1)`

Topper's Solved these Questions

WAVES AND OSCILLATIONS
ALLEN |Exercise Part-1(Exercise-05)[A]|28 Videos
SEMICONDUCTORS
ALLEN |Exercise Part-3(Exercise-4)|50 Videos

Similar Questions

Explore conceptually related problems

A particle executes two types of SHM. x_(1) = A_(1) sin omega t " and "x_(2) = A_(2) sin [omega t+(pi)/(3)] , then find the displacement at time t=0.

The displacement of a progressive wave is represented by y= A sin (omegat-kx) where x is distance and t is time. Write the dimensional formula of (i) w and (ii) k.

Displacement of two light waves are e_(1)=4 sin omega t and e_(2)= 3 sin (omegat + pi/2) . so amplitude of resultant wave = .....

cos(2pi -x) cos (-x) - sin(2pi +x) sin (-x) = 0

The length of metallic wire is l. The tensin in the wire is T_(1) for length l_(1) and tension in the wire is T_(2) for length l_(2). Find the original length.

A wire of length L and radius r is clamped rigidly at one end. When the other end of the wire is pulled by a force f its length increases by l. Another wire of the same material of length 2L and radius 2r is pulled by a force 2f. Then find the increase in length of this wire.

Two particle of medium disturbed by the wave propagation are at x_(1)=0 and x_(2)=1 cm . The respective displacement (in cm) of the particles can be given by the equation: y_(1)=2 sin 3pi t, y_(2)= 2 sin (3pi t-pi//8) the wave velocity is

A wire carrying a current i is placed in a uniform magnetic field in the form of the curve y=asin((pix)/L),0lexle2L . The force acting on the wire is

ALLEN -WAVES AND OSCILLATIONS-Part-1(Exercise-05)[B]

A train moves towards a stationary observer with speed 34 m//s. The tr...
Text Solution
|
Two vibrating strings of the same material but lengths L and 2L have ...
Text Solution
|
The ends of a stretched wire of length L are fixed at x = 0 and x = L....
Text Solution
|
Two pulse in a stretched string whose centers are initially 8cm apart ...
Text Solution
|
A siren placed at a railway platform is emitting sound of frequency 5 ...
Text Solution
|
A sonometer wire resonates with a given tuning fork forming a standing...
Text Solution
|
A police car moving at 22 m/s, chases a motorcylist. The police man so...
Text Solution
|
In the experiment for the determination of the speed of sound in air u...
Text Solution
|
A source of sound of frequency 600 Hz is placed inside water. The spee...
Text Solution
|
A closed organ pipe of length L and an open organ pipe contain gass of...
Text Solution
|
A source of sound of frequency 600 Hz is placed inside water. The spee...
Text Solution
|
An open pipe is in resonance in 2nd harmonic with frequency f(1). Now ...
Text Solution
|
A tuning fork of 512 H(Z) is used to produce resonance in a resonance ...
Text Solution
|
A massless rod BD is suspended by two identical massless strings AB an...
Text Solution
|
A transverse sinusoidal wave moves along a string in the positive x-di...
Text Solution
|
A vibrating string of certain length l under a tension T resonates wit...
Text Solution
|
The (x, y) co-ordinates of the corners of a square plate are (0, 0), (...
Text Solution
|
A transverse sinusoidal wave of amplitude a, wavelength lambda and fre...
Text Solution
|
As a wave propagates,
Text Solution
|
y(x, t) = 0.8//[4x + 5t)^(2) + 5] represents a moving pulse, where x a...
Text Solution
|