A particle of mass (m) is attached to a ...

A particle of mass (m) is attached to a spring (of spring constant k) and has a narural angular frequency omega_(0). An external force `R(t)` proportional to cos omegat(omega!=omega)(0) is applied to the oscillator. The time displacement of the oscillator will be proprtional to.

Topper's Solved these Questions

OSCILLATIONS
SL ARORA|Exercise Problem|23 Videos
OSCILLATIONS
SL ARORA|Exercise Problems for self practice|67 Videos
OSCILLATIONS
SL ARORA|Exercise Type D Based on Other Examples of SHM|2 Videos
MOTION IN ONE DIMENSION
SL ARORA|Exercise problems for self practice|66 Videos
Physical world
SL ARORA|Exercise Exercise|49 Videos

Similar Questions

Explore conceptually related problems

A particle of mass m is attached to three identical springs of spring constant k as shwon in figure. The time period of vertical oscillation of the particle is

A body of mass 1 kg oscillates on a spring of force constant 16 N/m. Calculate the angular frequency.

A body of mass 16 kg is made to oscillate on a spring of force constant 100 N kg^(-1) . Deduce the angular frequency.

If a body of mass 0.98 kg is made to oscillate on a spring of force constant 4.84 N/m the angular frequency of the body is

An object of mass m, oscillating on the end of a spring with spring constant k has amplitude A. its maximum speed is

When a particle of mass m is attached to a vertical spring of spring constant k and released, its motion is described by y (t) = y_0 sin^2omegat , where 'y' is measured from the lower end of unstretched spring. Then omega is :

A particle of mass m is fixed to one end of a massless spring of spring constant k and natural length l_(0) . The system is rotated about the other end of the spring with an angular velocity omega ub gravity-free space. The final length of spring is

A particle of mass m is attached with three springs A,B and C of equal force constancts k as shown in figure. The particle is pushed slightly against the spring C and released. Find the time period of oscillation. .

SL ARORA-OSCILLATIONS-Example

The time period of a mass suspended from a spring is T if the spring i...
Text Solution
|
Two simple harmonic are represented by the equation y(1)=0.1 sin (100p...
Text Solution
|
A particle of mass (m) is attached to a spring (of spring constant k) ...
Text Solution
|
A simple pendulum has time period T(1). The point of suspension is now...
Text Solution
|
The bob of simple pendulum executes SHM in water with a period T, whil...
Text Solution
|
A mass (M) is suspended from a spring of negligible mass. The spring i...
Text Solution
|
Two bodies (M) and (N) of equal masses are suspended from two separate...
Text Solution
|
A particle at the end of a spring executes simple harmonic motion with...
Text Solution
|
A particle executes simple harmonic motion between x = -A and x = + A....
Text Solution
|
Two simple harmonic motions are represented by the following equations...
Text Solution
|
A point particle of mass 0.1 kg is executing SHM of amplitude 0.1m. Wh...
Text Solution
|
A simple harmonic motion has an amplitude A and time period T. What is...
Text Solution
|
A block is resting on a piston which is moving vertically with simple ...
Text Solution
|
A block is kept on a horizontal table. The stable is undergoing simple...
Text Solution
|
Springs of spring constants k, 2k, 4k, 8k, …… are connected in series....
Text Solution
|
A uniform spring whose unstretched length is l has a force constant k....
Text Solution
|
A horizontal spring block system of mass M executes simple harmonic mo...
Text Solution
|
The bob of pendulum of length l is pulled aside from its equilibrium p...
Text Solution
|
A spring balance has a scale that reads from 0 to 50kg. The length of ...
Text Solution
|
A spring of force constant 1200Nm^(-1) is mounted on a horizontal tabl...
Text Solution
|