A particle of mass m moves along a curve `y=x^2`. When particle has x-coordinate as `(1)/(2)` m and x-component of velocity as `4(m)/(s)`, then

A particle of mass m movies along a curve y=x^(2) . When particle has x-co-ordinate as 1//2 and x-component of velocity as 4 m//s . Then :-

A particle moves along the curve 12y=x^(3) . . Which coordinate changes at faster rate at x=10 ?

A particle moves along a path y = ax^2 (where a is constant) in such a way that x-component of its velocity (u_x) remains constant. The acceleration of the particle is

A time varying force, F=2t is acting on a particle of mass 2kg moving along x-axis. velocity of the particle is 4m//s along negative x-axis at time t=0 . Find the velocity of the particle at the end of 4s.

A particle moves along the parabolic path x = y^2 + 2y + 2 in such a way that Y-component of velocity vector remains 5ms^(-1) during the motion. The magnitude of the acceleration of the particle is

A particle moves along the curve y=x^2 + 2x . At what point(s) on the curve are x and y coordinates of the particle changing at the same rate?

A particle moves along the curve y=(2/3)x^3+1. Find the points on the curve at which the y-coordinate is changing twice as fast as the x-coordinate

A particle moves along the curve y= (2/3)x^3+1 . Find the points on the curve at which the y-coordinate is changing twice as fast as the x-coordinate.

A particle of mass m1 is moving with a velocity v_(1) and another particle of mass m_(2) is moving with a velocity v2. Both of them have the same momentum but their different kinetic energies are E1 and E2 respectively. If m_(1) gt m_(2) then

A particle moves along a parabolic path y=-9x^(2) in such a way that the x component of velocity remains constant and has a value 1/3m//s . Find the instantaneous acceleration of the projectile (in m//s^(2) )