A particle moving with g uniform retardation covers distance 18 m .14 m and 10 m in successive seconds .It comes to rest after travelling a further distance of

A body moving with uniform retardation covers 3 km before its speed is reduced to half of its initial value. It comes to rest in another distance of

A particle moving with a uniform acceleration along a straight line covers distances a and b in successive intervals of p and q second. The acceleration of the particle is

A body moving with uniform acceleration covers a distance of 14 m in first 2 second and 88 m in next 4 second. How much distance is travelled by it in 5^(th) second?

A particle starts from rest and traverses a distance l with uniform acceleration, then moves uniformly over a further distance 2l and finally comes to rest after moving a further distance 3l under uniform retardation. Assuming entire motion to be rectilinear motion the ratio of average speed over the journey to the maximum speed on its ways is

A body covers 4.9m, 14.7 m, 24.5 m and 34.3m in the successive seconds of motion. The acceleration of the body is

A body starts from rest and travels a distance S with unitorm acceleration, then moves uniformly a distance 2S uniformly , and finally cones to rest after moving further 5S under uniform retardation. The ratio of the average velocity to maximum velocity is.

A train moving with uniform speed covers a distance of 120 m in 2 s. Calculate : (i) the speed of the train, (ii) the time it will take to cover 240 m.

metro train starts from rest and in five seconds achieves a speed 108 km/h. After that it moves with constant velocity and comes to rest after travelling 45m with uniform retardation. If total distance travelled is 395 m, find total time of travelling.

A particle starts moving with acceleration 2 m//s^(2) . Distance travelled by it in 5^(th) half second is

A stone of mass 1 kg is thrown with a velocity of 20 m/s across the frozen surface of a take and it comes to rest after travelling a distance of 50 m . What is the magnitude of the force opposing the motion of the stone ?