A car runs at constant speed around the horizontal race track shown in the figure. Over which portion of the track is the magnitude of the acceleration the greatest?

A bob is hanging over a pulley inside a car through a string. The second end of the string is in the hands of a person standing in the car. The car is moving with constant acceleration a directed horizontally as shown in fig. The other end of the string is pulled with constant acceleration a vertically. The tension in the string is equal to

A car moves around a curve at a constant speed. When the car goes around the arc subtending 60^(@) at the centre, then the ratio of magnitude of instantaneous acceleration to average acceleration over the 60^(@) arc is :

A car moves around a curve at a constant speed. When the car goes around the arc subtending 60^(@) at the centre, then the ratio of magnitude of instantaneous acceleration to average acceleration over the 60^(@) arc is :

A small roller coaster starts at point A with a speed u on a curved track as shown in the figure The friction between the roller coaster and the track is negligible and it always remains in contact with the track. The speed of roller coaster at point D on the track will be

A train is running at a constant speed of 90 km/h on a straight track. A person standing at the top of a boggey moves in the direction of motion of the train such that he covers 1 meters on the train each second. The speed of the person with respect to ground to -

A bead of mass m is released from rest at A to move along the fixed smooth circular track as shown in figure. The ratio of magnitudes of centripetal force and normal reaction by the track on the bead at any point P_0 described by the angle theta(!=0) would

A car moves at a constant speed on a road as shown in figure. The normal force by the road on the car is N_A and N_B when it is at the points A and B respectively .

A car moving with a constant speed on a straight track takes a band in a curve with the same speed. Due to this

A car travels with constant speed on a circular road on level ground. In the figure shown, F_(air) is the force of air resistance on the car. Which of the other forces best represent the horizontal force of the road on the car's tires ?

A car is moving along a circle with constant speed on an inclined plane as shown in diagram. Then friction force on car will be in horizontal direction at least at one point :