A cyclist going around a circular road of radius 10 m is observed to be bending inward `30^@` with vertical. Frictional force acting on the cyclist is (Given:g=10`m//s^2`, mass of the cyclist is 90 kg)

A scooter is going round a circular road of radius 100 m at a speed of 10 m//s . The angular speed of the scooter will be

A cyclist moves around a circular path of radius 40sqrt3 m with a speed of 20 m//s . He must lean inwards at an angle theta with the vertical such that tan theta is equal to

A cyclist is moving on a circular track of radius 80 m with a velocity of 72 km/hr. He has to lean from the vertical approximately through an angle

A cyclist is moving in a circular track of radius 80 m with a velocity v =36 kmh^(-1) . He has to lean from the vertical approximately through an angle

A motor cyclist going round on unbanked circular race course has to lean inwards, making an angle 21^(@) 49 ' with the vertical , in order to keep his balance. If the curve is 1 km long , then the speed of the cyclist will be, ( tan 21^(@) 49 =0.4003' g=9.8 m//s ^(2) )

A circular road of radius 50m has the angle of banking equal to 30^(@) . At what should a vehicle go on this road so that the friction is not used?

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 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 :