Calculate the angle of banking required for a curve of 200 m radius so that a car rounding the curve at 80 kph would have no tendency to skid outward or inward. Assume the surface is frictionless. Take `g=10m//s^(2)`

Find the horizontal velocity of the particle when it reach the point Q. Assume the block to be frictionless. Take g=9.8 m//s^(2) .

Calculate the tension in the string shown in figure. The pulley and the string are light and all surfaces are frictionless. Take g=10 m/ s^2 .

Calculate the tension in the string shown in (a) The pulleys and the string are light and all surfaces are frictionless. (g=10m//s^(2))

In the figure shoen calculate the angle of friction . The block dows not slide. Take g=10(m)/(s^2) .

Which driving a car around a curve of 200 m radius ,the driver notices that a simple rendulum hung to the roof of the car is marking an angle of 15^(@) to the horizontal ,what is the speed of the car km /h ? (g=10m//s^(2))("use " tan 15^(@)=0.2645)

Find the maximum speed at which a car can turn round a curve of 30 m radius on a level road if coefficient of friction between the tyress and road is 0.4. Take g = 10 m//s^(2) .

Find the maximum speed at which a car can take turn round a curve of 30 cm radius on a level road if the coefficient of friction between the tyres and the road is 0.4. Take g = 10 ms^(-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 small block of mass m=2kg is at rest point P of the stationary wedge having frictionless hemispherical track of radius R=4m . The minimum constant acceleration 'a_(0)' ( in m//s^(2) ) is to be given to the wedge in horizontal direction, so that the small block just reaches the point Q as shown in figure. Assume all the contacts are frictionless and g=10m//s^(2) . If a_(0)=2xm//s^(2) . Find the value of x