A body moves so that it follows the following relation `(dv)/(dt)=-v^(2)+2v-1` where v is speed in m/s and t is time in second. If at t=0, v=0 then find the speed (in m/s) when acceleration in one fourth of its initial value.

The motion of a body is given by the equation (dv)/(dt)=4-2v , where v is the speed in m/s and t in second. If the body was at rest at t = 0, then find (i) The magnitude of initial acceleration (ii) Speed of body as a function of time

The motion of a particle moving along x-axis is represented by the equation (dv)/(dt)=6-3v , where v is in m/s and t is in second. If the particle is at rest at t = 0 , then

Equation of motion of a body is (dv)/(dt) = -4v + 8, where v is the velocity in ms^-1 and t is the time in second. Initial velocity of the particle was zero. Then,

If v=3t^(2) - 2t +5 , where v is velocity (in m/s) and t is time (in second). Find the displacement (in m) of particle in third second. (A) 19 (B) 24 (C) 9 (D) None of these

The velocity of a particle defined by the relation v = 8 -0.02x, where v is expressed in m/s and x in meter. Knowing that x = 0 at t = 0, the acceleration at t=0 is

A particle in moving in a straight line such that its velocity is given by v=12t-3t^(2) , where v is in m//s and t is in seconds. If at =0, the particle is at the origin, find the velocity at t=3 s .

The motion of a body is given by the equation dv//dt=6-3v , where v is in m//s. If the body was at rest at t=0 (i) the terminal speed is 2 m//s (ii) the magnitude of the initial acceleration is 6 m//s^(2) (iii) The speed varies with time as v=2(1-e^(-3t)) m//s (iv) The speed is 1 m//s , when the acceleration is half initial value

The speed(v) of a particle moving along a straight line is given by v=(t^(2)+3t-4 where v is in m/s and t in seconds. Find time t at which the particle will momentarily come to rest.

A long plank begins to move at t=0 and accelerates along a straight track wit a speed given by v=2t^(2) for 0le t le 2 (where v is in m/s and t is in second). After 2 sec the plane continues to move at the constant speed acquired. A small initially at rest on the plank begins to slip at t=1 sec and stops sliding at t=3 sec. If the coefficient of static friction and kinetic friction between the plank and the block is 0.s and 0.k (where s and k are digits) respectively, find s+k (take g=10m//s^(2) )

The velocity of a particle moving on the x-axis is given by v=x^(2)+x , where x is in m and v in m/s. What is its position (in m) when its acceleration is 30m//s^(2) .