The amplitude of a particle under forced vibration is given as `A=10/(x^2-5x+6)`. Resonance will takes place at x equal to

The velocity of a particle moving along x-axis is given as v=x^(2)-5x+4 (in m // s) where x denotes the x-coordinate of the particle in metres. Find the magnitude of acceleration of the particle when the velocity of particle is zero?

The potential energy of a particle under a conservative force is given by U ( x) = ( x^(2) -3x) J. The equilibrium position of the particle is at

Potential energy of a particle at position x is given by U=x^(2)-5x . Which of the following is equilibrium position of the particle?

The position of a particle moving on a stringht line under rthe action of a force is given as x=50t-5t^(2) Here, x is in metre and t is in second. If mass of the particle is 2 kg, the work done by the force acting on the particle in first 5 s is.

The rate of doing work by force acting on a particle moving along x-axis depends on position x of particle and is equal to 2x. The velocity of particle is given by expression :-

For a particle showing motion under forces F= - 5 ( x-2)^(2) , the motion is

Graphs shows the acceleration of a 3 kg particle as an applied force moves it from rest along x-axis. The total work done by the force on the particle by the time the particle reaches x = 6 m, is equal to

A force F is related to the position of a particle by the relation F=(10x^(2))N . Find the work done by the force when the particle moves from x=2m to x=4m .

The equation of a travelling sound wave is y = 6.0 sin (600 t - 1.8 x) where y is measured in 10^-5m , t in second and x in metre. (a) Find the ratio of the displacement amplitude of the particles to the wavelength of the wave. (b) Find the ratio of the velocity amplitude of the particles to the wave speed.

Potential energy of a particle moving along x-axis under the action of only conservative force is given as U=10+4cos(4pi x) . Here, U is in Joule and x in metres. Total mechanial energy of the particle is 16 J. Choose the correct option.