The vertical motion of a ship at sea is described by the equation `(d^2(x))/(dt^(2))=-4x` , where x is the vertical height of the ship (in meter) above its mean position. If it oscillates through a height of 1 m

The roots of the equation x^(4)-2x^(2)+4=0 are the vertices of a :

A particle travels according to the equation y=x-(x^(2)/(2)) . Find the maximum height it acheives (x and y are in metre)

The equation of motion of a particle of mass 1g is (d^(2)x)/(dt^(2)) + pi^(2)x = 0 , where x is displacement (in m) from mean position. The frequency of oscillation is (in Hz)

A body is projected horizontally from a point above the ground. The motion of the body is described by the equations x = 2 t and y= 5 t^2 where x and y are the horizontal and vertical displacements (in m) respectively at time t. What is the magnitude of the velocity of the body 0.2 second after it is projected?

The acceleration of a particle moving in straight line is defined by the relation a= -4x(-1+(1)/(4)x^(2)) , where a is acceleration in m//s^(2) and x is position in meter. If velocity v = 17 m//s when x = 0 , then the velocity of the particle when x = 4 meter is :

If a simple harmonic motion is represented by (d^(2)x)/(dt^(2)) + alphax = 0 , its time period is :

An arch is built so that it has the shape of a parabola with the equation y=-3x^(2)+24x where y represents the height of the arch in meters. How many times greater is the maximum height of the arch than the width of the arch at its base?

The position 'x' of a particle moving along x-axis at any instant t represent by given equation t= sqrtx+3, where x is in M , where x is in meters and t is in seconds. The position of particle at the instant when its velocity is zero.

A motion is described by Y = 4e^(x) (e ^- (5t)) , Where y,x are in meters and t is in second .

What is the velocity of the bob of a simple pendulum at its mean position, if it is able to rise to vertical height of 10 cm (take g=9.8m//s^(2) )