Figure shows the kinetic energy `K` of a simple pendulum versus its angle `theta` from the verticle. The pendulum bob has mass `0.2 kg`. If the length of the pendulum is equal to `(n)/(g)` meter. Then find `n (g = 10 m//s^(2))`

Figure shown the kinetic energy K of a pendulum versus. its angle theta from the verticle. The pendulum bob has mass 0.2kg The length of the pendulum is equal to (g = 10m//s^(2)) ,

The given figure shows the variation of the kinetic energy of a simple pendulum with its angular displacement (theta) from the vertical. Mass of the pendulum bob is m = 0.2 kg. Find the time period of the pendulum. Take g = 10 ms^(-2) .

The angle made by the string of a simple pendulum with the vertical depends on time as theta=pi/90sin[(pis^-1)t] . Find the length of the pendulum if g=pi^2ms^-2

Assertion : If the length of the simple pendulum is equal to the radius of the earth, the period of the pendulum is T=2pisqrt(R//g) Reason : Length of this pendulum is equal to radius of earth.

A simple pendulum is released from A as shown. If m and 1 represent the mass of the bob and length of the pendulum, the gain kinetic energy at B is

Instantaneous angle (in radian) between string of a simple pendulum and verical is given by theta = (pi)/(180) sin2pit . Find the length of the pendulum if g = pi^(2) m//s^(2) .

The period of a simple pendulum is double, when its length is increased by 1.2 m. The original length of the simple pendulum is

A bullet of mass m strikes a pendulum bob of mass 2m with velocity u es shown in figure. If passes through and emerges but with a velocity u//2 from bob. The length of the pendulum bob is l = 2m . If the minimum value of u for which the pendulum bob completes full circle is 10X m//s , then find X . (Take g = 10 m//s^(2) )

A 1N pendulum bob is held at an angle theta from the vertical by a 2N horizontal force F as shown in figure. The The tension in the string supporting the pendulum bob (in newton) is .