The bob of pendulum is project with horizontal velocity of `sqrt(3gf)` I is the length of string. Find the angular displacement of string before it becomes slack.

The bobo of a pendulum at rest is given a sharp hit to impart a horizontal velocity u where l is the length of the pendulum. Find the angle rotated by the string before it becomes slack.

The bob of a stationary pendulum is given a sharp hit to impart it a horizontal speed of sqrt(3gl) . Find the angle rotated by the string before it becomes slack.

The bob of a pendulum at rest is given a sharp hit to impart a horizontal velocity sqrt(10 gl) where l is the length of the pendulum. Find the tension in the string when a. the string is horizontal. B. The bob is at its highest point and c. the string makes an angle of 60^0 with the upward vertical.

A heavy particle hangs from a point O, by a string of length a. It is projected horizontally with a velocity u = sqrt((2 + sqrt(3))ag) . The angle with the downward vertical, string makes where string becomes slack is :

A bob of mass m is projected with a horizontal velocity v=sqrt((gl)/(2)) as shown in figure. In consequence, it moves in a circular path in a vertical plane by the inextensible string which passes over the smooth fixed peg. Find the maximum angle that the bob swings in the left hand side.

A heavy particle hanging from a fixed point by a light inextensible string of length l is projected horizontally with speed (gl) . Then the speed of the particle and the inclination of the string to the vertical at the instant of the motion when the tension in the string equal the weight of the particle-

The string of a pendulum is horizontal. The mass of the bob is m. Now the string is released. The tension in the string in the lowest position is -

A mass is supported on a frictionless horizontal surface. It is attached to a string and rotates about a fixed centre with a angular velocity omega_(0) . If the length of the string and angular velocity are doubled, the tension in the string which was initially T_(0) is now

A block of mass m is attached to a pulley disc of equal mass, radius r by means of a slack string as shown. The pulley is hinged about its centre on a horizontal table and the block is projected with an initial velocity of 5 m//s . Find the velocity when the string becomes taut. .

A heavy particle hanging from a string of length I is projected horizontally with speed sqrt(gl) . Find the speed of the particle at the point where the tension in the string equals weight of the particle.