When the string of a conical pendulum makes an angle of `45^(@)` with the vertical , its time is `T_(1)` when the string makes an angle of `60^(@)` with the vertical , its time period is `T_(2)` then `T_(1)^(2) // T_(2)^(2)`is

A conical pendulum of length L makes an angle theta with the vertical. The time period will be

If the string of a conical pendulum makes an angle theta with horizontal, then square of its time period is proportional to

A kite is attached to a string. Find the length of the string , when the height of the kite is 60 m and the string makes an angle 30^(@) with the ground .

A pendulum bob has a speed of 3ms^(-1) at its lowest position. The pendulum is 0.5 m long. The speed of the bob, when string makes an angle of 60^(@) to the vertical is ("take, g"=10ms^(-1))

The distance time graph of a particle at time t makes angle 45^(@) with respect to time axis. After 1s , if makes angle 60^(@) with respect to time axis. What is the acceleration of the particle?

Consider a pair of identical pendulums, which oscillate with equal amplitude independently such that when one pendulum is at its extreme position making an angle of 2^(@) to the right with the vertical, the other pendulum makes an angle of 1^(@) to the left of the vertical. What is the left of the vertical. What is the phase difference between the pendulums?

Consider a pair of identical pendulums, which oscillate with equal amplitude independently such that when one pendulum is at its extreme position making an angle of 2^(@) to the right with the vertical , the other pendulum makes an angle of 1^(@) to the left of the vertical. What is the phase difference between the pendulums?

A kite is attached to a 100 m long string. Find the greatest height reached by the kite when its string makes an angle of 60^(@) with the travel round.

Determine the tensions T_(1) and T_(2) in the string as shown in figure.

Determine the tensions T_(1) and T_(2) in the string as shown in figure.