A puck of mass `m` is moving in a circle at constant speed on a frictionless table as shown in the figure . The puck is connected by a string to a suspended bob, also of mass `m`, which is at rest below the table. Half of the length of the string is above the tabletop and half below. What is the magnitude of the centripetal acceleration of the moving puck ? Let `g` be the acceleration due to gravity.

Two blocks, each having mass m, are connected with an ideal string through ideal pulleys on a frictionless fixed wedge as shown in the figure. The acceleration of the blocks is

A block of mass m is tied to a string of length L and the assembly is kept on a smooth horizontal table as shown in the figure. Now the other end of the string is moved with a constant velocity v_(0)hatj . ( xy plane is the plane of the table) Then

A body of mass m is moving in a circle of radius r with a constant speed v. The work done by the centripetal force in moving the body over half the circumference of the circle is

Two blocks, each having a mass M, rest on frictionless surfaces as shown in the figure. If the pulleys are light and frictionless and M on the incline is allowed to move down, then the tension in string will be

A particle of mass m is moving in a circle of radius (r) with changing speed (v) the direction of centripetal force and tangential force are shown below the value of alpha is

The magnitud of difference in accelerations of blocks of mass m in . Both the cases shown below is

The block shown in figure has a mass M and descends with an acceleration a. The mass of the string below the point A is m. Find the tension of the string at the point A and at the lower end.

A uniform rod of mass m and length L is kept on a horizontal table with L/4 length on the table as shown in figure. As the string attached to the end B is cut, the angular acceleration of the rod about point C will be

Two blocks are connected by a massless string that passes over a frictionless peg as shown in figure. One end of the string is attached to a mass m_1=3kg , i.e., a distance R=1.20m from the peg. The other end of the string is connected to a block of mass m_2=6kg resting on a table. From what angle theta , measured from the vertical, must the 3-kg block be released in order to just lift the 6kg block off the table?

Three blocks of masses m, 3m and 5m are connected by massless strings and pulled by a force F on a frictionless surface as shown in the figure below. The tension P in the first string is 16N. If the point of application of F is changed as given below. The values of P' and Q' shall be