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 A, Energy is (g = acceleration due to gravity)

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

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

STATEMENT -1 : If a simple pendulum is in a carriage which is accelerating downward and acceleration is greater than acceleration due to gravity , then pendulum turns up side down and oscillates about highest point. and STATEMENT -2 : The time period of pendulum will be independent of g in above case of pendulum oscillating about highest point.

STATEMENT -1 : If a simple pendulum is in a carriage which is accelerating downward and acceleration is greater than acceleration due to gravity , then pendulum turns up side down and oscillates about highest point. and STATEMENT -2 : The time period of pendulum will be independent of g in above case of pendulum oscillating about highest point.

Consider a simple pendulum. The period of oscillation of the simple pendulum depends on its length and acceleration due to gravity. Then the expression for its time period is

The period of oscillation of a simple pendulum at a given place with acceleration due to gravity 'g' depends on

A positively charged pendulum is oscillating in a uniform electric field as shown in Figure. Its time period of SHM as compared to that when it was uncharged. (mg gt qE)

A positively charged pendulum is oscillating in a uniform electric field as shown in Figure. Its time period of SHM as compared to that when it was uncharged. (mg gt qE)

A simple pendulum is oscillating in a stationery lift. When the lift falls freely, the frequency of oscillations of the pendulum is