A curved road is banked for speed `v_(0)`. When a car moves along the road with a constant speed `v`, the force the friction between the road and the tyres is F. Which of the following statements(s) is (are) correct ?

A car moves along a horizontal circular road of radius r with velocity u -The coefficient of friction between the wheels and the road is mu . Which of the following statement is not true?

A cyclist moves along a curved road with a velocity v. The road is banked for speed v. The angle of banking is theta .Which of the following statements in not true?

A car starts moving from rest on a horizontal circular road of radius of curvature R at . The speed of the car is increasing at a constant rate a. The coefficient of friction between the road and the tyres of the car is The car starts slipping at time t = t_(0) . Then t_(0) is equal to:

A vehicle of mass M is moving on a rough horizontal road with a momentum P If the coefficient of friction between the tyres and the road is mu is then the stopping distance is .

A body moves along an uneven horizontal road surface with constant speed at all points. The normal reaction of the road on the body is

A vehicle is travelling along unbanked curved path. If the friction between the road and tyres suddenly disappears then the vehicle

A car goes on a horizontal circular road of radius R. The speed of car is increasing at constant rate a m/ s^2 . If the friction coefficient between the road and the tyre is mu , then the limiting speed of car is

A circular road of radius r is banked for a speed v=40 km/hr. A car of mass m attempts to go on the circular road. The firctioncoefficient between the tyre and the road is negligible.

A cyclist speeding at 4.5 km/h on a level road takes a sharp circular turn of radius 3 m without reducing the speed. The coefficient of static friction between the road and the tyres is 0.1. (i) Will he slip while taking the turn? (ii) Will he slip if his speed is 9 km/h?

A car is moving along a straight horizontal road with a speed v_(0) . If the coefficient of friction between the tyres and the road is mu , the shortest distance in which the car can be stopped is