For a simple pendulum, the graph between `T^(2) and L` (where T is the time period & Lis the length) is

For a simple pendulum the graph between length and time period will be

The l - T^(2) graph of a simple pendulum is an shown in the figure. The time period of the pendulum of length 0.5 mm is

The time period of a simple pendulum is given by the formula, T = 2pi sqrt(l//g) , where T = time period, l = length of pendulum and g = acceleration due to gravity. If the length of the pendulum is decreased to 1/4 of its initial value, then what happens to its frequency of oscillations ?

Time period of is simple pendulum of length L is T_(1) and the point time peirod of a uniform rod of the same length L pivotal about one end and oscillating in vertical plane is T_(2) . Amplitude of oscillation in both the cased is small. The T_(1)//T_(2) is:

The graph between the length and square of the period of a simple pendulum is a

Time period of a simple pendulum of length L is T_(1) and time period of a uniform rod of the same length L pivoted about an end and oscillating in a vertical plane is T_(2) . Amplitude of osciallations in both the cases is small. Then T_(1)/T_(2) is

A simple pendulum of length l_(1) has a time period of 4 s and another simple pendulum of length l_(2) has a time period 3 s. Then the time period of another pendulum of length (l_(1)-l_(2)) is

The time period of a simple pendulum in a stationary train is T. The time period of a mass attached to a spring is also T. The train accelerates at the rate 5 ms^(-2) . If the new time periods of the pendulum and spring be T_(p) and T_(s) , respectively. Then,