In the previous question the smallest kinetic energy at the bottom of the incline will be achieved by

A solid sphere, a hollow sphere and a disc, all having same mass and radius, are placed at the top of an incline and released. The friction coefficients between the objects and the incline are same and not sufficient to allow pure rolling. The smallest kinetic energy at the bottom of the incline will be achieved by

Solid Sphere, Ring and Disc having same mass m and radius r the smallest kinetic energy at the bottom of the incline will be achieved by 1)Solid Sphere 2)Ring 3)Disc 4)All will achieve the same kinetic energy

in the previous question, the change in potential energy.

in the previous question, the change in potential energy.

A solid spherical ball is released from rest on an incline of inclination angle theta (which can be varied ) but through a fixed vertical height h . The coefficient of static and kinetic friction are both equal to mu . If E represents the total kinetic energy of the ball at the bottom of the incline as a function of the angle of inclination theta . W represents the work done by friction for the whole time of motion as a function of the angle of inclination theta . Choose of correct graph (s)

A solid ball is realeased from rest down inclines of various inclination angle theta but through a fixed vertical height h. The coefficient of static and kinetic friction are both equal to mu . Which of the following graph best represents the total kinetic energy K of the ball at the bottom of the incline as a function of the angle theta of the incline?

A solid ball is realeased from rest down inclines of various inclination angle theta but through a fixed vertical height h. The coefficient of static and kinetic friction are both equal to mu . Which of the following graph best represents the total kinetic energy K of the ball at the bottom of the incline as a function of the angle theta of the incline?