In the above problem car got a stopping distance of `80m` on cement road then `mu_(k)` is `(g = 10 m//sec^(2))` .

A stone is relased from top of a lower. It covers a distance of 80m in last 2 seconds of its motion. Then the height of the lower is : (g = 10 m//s^(2))

A car is moving with speed v and is taking a turn on a circular road of radius 10 m. The angle of banking is 37^(@) . The driver wants that car does not slip on the road. The coefficient of friction is 0.4 (g = 10 m//sec^(2)) The speed of car for which no frictional force is produced is :

A car is moving with speed v and is taking a turn on a circular road of radius 10 m. The angle of banking is 37^(@) . The driver wants that car does not slip on the road. The coefficient of friction is 0.4 (g = 10 m//sec^(2)) The friction force acting when v=10 m//sec and mass of car is 50 kg is :

A car running with a velocity 72 kmph on a level road is stoped after travelling a distance of 30m after disengaging its engine (g =10m^(-2)) The coefficient of friction between the road and the tyres is .

A ball is thrown vertically downward with a velocity of 20m/s from the top of a tower,It hits the ground after some time with a velocity of 80m/s .The height of the tower is : (g=10m/g^(2))

A ball is projected with a velocity of 20 m//s vertically. Find the distance travelled in first three second. (use g = 10 m//sec^(2) )

A car is moving with speed v and is taking a turn on a circular road of radius 10 m. The angle of banking is 37^(@) . The driver wants that car does not slip on the road. The coefficient of friction is 0.4 (g = 10 m//sec^(2)) If the car were moving on a flat road and distance between the front tyres is 2 m and the height of the centre of the mass of the car is 1m from the ground, then, the minimum velocity for which car topples is :