At what displacement the kinetic is equal to the potential energy ?
Hint `: U = (1)/(2) kx^(2) , K = (1)/(2) (A^(2) - x^(2))`
`U = K`

For Question , calculat the block's speed asit passes through the equilibrium point ? Hint : E = K+U = (1)/(2) mv^(2) + (1)/(2) kx^(2) = (1)/(2) mv^(2) +0 . Calculate v

A particle slides on frictionless x - y plane. It is acted on by a conservative force described by the potential - energy function U(x, y) =(1)/(2)k(x^(2)+y^(2)) . Derive an expression for the force acting on the particle.

A particle is moving on frictionless XY-plane. It is acted on by a conservative force described by the potential-energy function. U(x,y,z)=(1)/(2)k(x^(2)+y^(2)+z^(2)) where , k=constant Derive an expression for the force an the particle.

Find the points of discontinuity of y = (1)/(u^(2) + u -2) , where u = (1)/(x -1)

(a) The motion of the particle in simple harmonic motion is given by x = a sin omega t . If its speed is u , when the displacement is x_(1) and speed is v , when the displacement is x_(2) , show that the amplitude of the motion is A = [(v^(2)x_(1)^(2) - u^(2)x_(2)^(2))/(v^(2) - u^(2))]^(1//2) (b) A particle is moving with simple harmonic motion is a straight line. When the distance of the particle from the equilibrium position has the values x_(1) and x_(2) the corresponding values of velocity are u_(1) and u_(2) , show that the period is T = 2pi[(x_(2)^(2) - x_(1)^(2))/(u_(1)^(2) - u_(2)^(2))]^(1//2)

If int x e^(kx^(2)) dx = ( 1)/( 4) e^(2x^(2)) + C , then the value of k is

The dimensions of K in the equation W=1/2Kx^(2) is

At two positons kinetic energy and potential energy of a particle are K_(1) =10J: U_(1) =-20J, K_(2) = 20 J, U_(2)=-10 J . In moving from 1 to 2 .

Discuss the continuity for f(x) = (1 - u^(2))/(2 + u^(2)) , where u = tan x.

A body executes simple harmonic motion. At a displacement x, its potential energy is U_1 . At a displacement y, its potential energy is U_2 . What is the potential energy of the body at a displacement (x + y)?