A simple pendulum of length 'L' has mass 'M' and it oscillates freely with amplitude A, Energy is
(g = acceleration due to gravity)

A simple pendulum with a bob of mass m oscillates from A to C and back to A such that PB is H. IF the acceleration due to gravity is g, the velocity of bob as it passes through B is

A simple pendulum of length L and mass M is oscillating about a vertical line with angular amplitude theta . If for an angular displacement phi (phi>theta) the tension in the string is T_1 and for angular amplitude theta the tension is T_2 , then

A simple pendulum of length 1m is allowed to oscillate with amplitude 2^(@) . it collides at T to the vertical its time period will be (use g = pi^(2) )

A simple pendulum of length 1 m with a bob of mass m swings with an angular amplitude 30^(@) . Then (g= 9.8m//s^(2)

A simple pendulm has a length L and a bob of mass M. The bob is vibrating with amplitude a .What is the maximum tension in the string?

Find the binding energy of a satellite of mass m in orbit of radius r , (R = radius of earth, g = acceleration due to gravity)

If unit of length and time is doubled the numerical value of g (acceleration due to gravity ) will be

A simple pendulum of length L has a period T. If length is changed by Delta L , the change in period Delta T is proportional to

The time period Of oscillation of a simple pendulum depends on the following quantities Length of the pendulum (l), Mass of the bob (m), and Acceleration due to gravity (g) Derive an expression for Using dimensional method.

A simple pendulum of length l has maximum angular displacement theta . Then maximum kinetic energy of a bob of mass m is