A tuck moving at 36 km. `h^(-1)` has to be brought to rest by applying brakes in such a way that there is no relative displacement of the goods in the truck with respect to the truck floor. Coefficient of friction between the goods and the truck floor is 0.2. Find the minimum distance the truck must move before it comes to rest .

A train moving at 54 "km.h^(-1) is brought to rest in 1 min on application of brakes. What is the retardation of the train? Also find the distance travelled by the train after application of the brakes.

A car of mass 1000 kg moves up at 40 km *h^(-1) along an inclined plane of slope 1/(50) . Coefficient of rolling friction between the road and the wheels of the car is 0.3. Find the power of the car engine.

A body moving on the surface of the earth at 14 "m.s"^(-1) comes to rest due to friction after covering 50 m. Find the coefficient of friction between the body and the earth's surface. Given, acceleration due to gravity = 9.8 "m.s"^(-2) .

A car of mass 500 kg is moving up along an inclined surface of slope 1/(25) at a constant speed of 72 km*h^(-1) . If the coefficient of friction between the road and the car wheel is 0.1 , find the power of the car engine (g= 9.8 m*s^(-2) ).

A cyclist moving on a level road at 4 m/s stops pedalling and lets the wheels come to rest. The retardation of the cycle has two components: a constant 0.08 m//s^2 due to friction in the working parts and a resistance of 0. 02v^2//m , where v is speed in meters per second. What distance is traversed by the cycle before it comes to rest? (consider ln 5=1.61).