A ball is held at rest in position A by two light cords. The horizontal cord is now cut and the ball swings to the position B. What is the ratio of the tension in the cord in position B to that in position A?

A ball of mass 1kg is at rest in position P by means two light strings OP and RP . The string RP is now cut and the ball swings to position Q . If theta =45^(@) . Find the tensions in the strings in position OP (when RP was not cut ) and OQ (when RP was cut ). (take g =10m//s^(2) ).

In the shown figure the tension in the horizontal cord is 30N. Find the weight of the body B.

A small mass m and its supporting wire because a simple pendulum when the horizontal cord is cut . Find the ratio of the tension in the supporting wire immediately after the cord is cut to the tension in the wire before the cord is cut

A small object of mass m, on the end of a light cord, is held horizontally at a distance r from a fixed support as shown. The object is then released. What is the tension in the cord when the object is at the lowest point of its swing?

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 ball of mass 0.1 kg is suspended by a string. It is displaced through an angle of 60^(@) and left. When the ball passes through the mean position, the tension in the string is

A ball is suspended from the accelerating car by two cords 'A' and 'B' . The acceleration 'a' of the car which will cause the tension in 'A' to be twice the tension in B, is

A small sphere B of mass m is released form rest in the position shown and swings freely in a vertical plane, first about O and then about the peg A after the cord comes in contact with the peg. Determime the tension in the cord (a) just before the sphere comes in contact with the peg. (b) just after it comes in contact with the peg.

A smooth circular tube is held in a vertical position. A small ball which is free to slide inside the tube is held stationary at the highest position in the tube. If the ball is slightly displaced from its position of rest, show that the force exerted by the ball on the wall of the tube is given as mg(3 costheta-2) , where m is the mass of the ball and theta is the angular displacement from highest position. Upto what value of theta , this result will remain valid.

A and B are two points. The position vector of A is 6b-2a. A point P divides the line AB in the ratio 1:2. if a-b is the position vector of P, then the position vector of B is given by