A motor cycle racer takes a round with speed 20ms 1 in a curvature of radius of R = 40m, then the leaning angle of motor cycle for safe turn is (g=`10ms-^2)`

A motor cyclist moving with a velocity of 72 km/hour on a flat road takes a turn on the road at a point where the radius of curvature of the road is 20 meters . The acceleration due to gravity is 10m//sec^(2) . In order to avoid skidding, he must not bend with respect to the vertical plane by an angle greater than

A moter-cyclist moving with a velocity of 144 kmh^(-1) on a flat road takes a turn on the road at a point where the radius of curvature of the road is 40 m. The acceleration due to gravity is 10 ms^(-2) . In order to avoid sliding, he must bend with respect to the vertical plane by an angle

A cyclist is moving on a smooth horizontal curved path of radius of curvature 10m .With a speed 10ms^(-1).Then his angle of leaning is (g=10ms^(-1))

A motor cycle is going on an over bridge of radius R. the driver maintains a constant speed. As motor cycle is descending, normal force on it

A motor cycle starts from rest and accelerates along a straight path at 2m//s^(2) . At the starting point of the motor cycle there is a stationary electric siren. How far has the motor cycle gone when the driver hears the frequency of the siren at 94% of its value when the motor cycle was at rest ? (Speed of sound = 330ms^(-2))

In a circus, a motor cyclist goes round a vertical circle inside a spherical cage of radius 4.5 m . Calculate the minimum speed of the motor cycle inside the cage.

A motor cylist moving with a velocity of 72 km / hour on a flat road takes a turn on the road at a point where the radius of curvature of the road is 20 m . The acceleration due to gravity is 10 m // sec ^(2) . In order to avoid skidding , he must not bend with respect to the vertical plane by an angle greater than

If the banking angle of curved road is given by tan^(-1)((3)/(5)) and the radius of curvature of the road is 6 m, then the safe driving speed should not exceed (take, g=10ms^(-2) )