If a simple pendulum has charge ,q and is oscillating in a uniform electric field E in the direction of acceleration due to gravity then its frequency of oscillations

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

An electron of mass m, charge e falls through a distance h metre in a uniform electric field E. Then time of fall

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' , then the velocity of the bob, as it passes through B, is

Two simple pendulum A and B of lengths 1.69m and 1.44m start swinging at the time from a location where acceleration due to gravity is 10ms^(-1) . Answer the following question. After how much time, the two pendulums will be in phase again ?

A magnetic field set up using Helmholtz coils is uniform in a small, region and has a magnitude of 0.75 T. In the same region a uniform electrostatic field is maintained in a direction normal to the common axis of the coils . A narrow beam of (single species) charged particles all accelerated through 15 kV enters this region in a direction perpendicular to both the axis of the coils and the electrostatic field . If the beam remains undeflected when the electrostatic field is 9.0 xx 10^-5 V m^-1 , make a simple guess as to what the beam contains . Why is the answer not unique ?

If the time period of a simple pendulum is T = 2pi sqrt(l//g) , then the fractional error in acceleration due to gravity is

The length of second 's pendulum on the surface of earth is nearly 1 m . Its length on the surface of moon should be [ Given : acceleration due to gravity (g) on moon is 1/6th of that on the earth 's surface]

A particle executing SHM has a maximum speed of 0.5ms^(-1) and maximum acceleration of 1.0ms^(-2) . The angular frequency of oscillation is

Consider a square loop of wire loaded with a glass bulb of mass m hanging vertically, suspended in air with its one part in a uniform magnetic field B with its direction coming out of the plane of paper. Due to the current I flowing through the loop, there is a magnetic force in upward direction calculate the current I in the loop for which the magnetic force would be exactly balanced by the force on mass m due to gravity.

When the length of a simple pendulum is increased by 36 cm, its time period of oscillation is found to increase by 25 %. The initial length of the simple pendulum 1s (Acceleration due to gravity= 9.8ms^(-2) )