Passage II) Two identicla blocks P and Q have masses m each. They are attached to two identical springs initially unstretched. Now the left spring (along with P) is compressed by `A/2` and the right spring (along with Q) is compressed by A. Both the blocks are released simultaneously. They collide perfectly inelastically. Initially time period of both blocks was T.

The amplitude of combined mass is

Two identical blocks P and Q have mass m each. They are attached to two identical springs initially unstretched. Now the left spring (along with P) is compressed by A//2 and the right spring (along with Q ) is compressed by A . Both the blocks are released simultaneously. They collide perfectly inelastically. Initially time period of both the blocks was T . The amplitude of combined mass is

Passage II) Two identicla blocks P and Q have masses m each. They are attached to two identical springs initially unstretched. Now the left spring (along with P) is compressed by A/2 and the right spring (along with Q) is compressed by A. Both the blocks are released simultaneously. They collide perfectly inelastically. Initially time period of both blocks was T. The time period of oscillation of combined mass is

Passage II) Two identicla blocks P and Q have masses m each. They are attached to two identical springs initially unstretched. Now the left spring (along with P) is compressed by A/2 and the right spring (along with Q) is compressed by A. Both the blocks are released simultaneously. They collide perfectly inelastically. Initially time period of both blocks was T. What is energy of osciallation of the combined mass?

Two identical blocks P and Q have mass m each. They are attached to two identical springs initially unstretched. Now the left spring (along with P) is compressed by A//2 and the right spring (along with Q ) is compressed by A . Both the blocks are released simultaneously. They collide perfectly inelastically. Initially time period of both the blocks was T . The time period of oscillation of combined mass is

Two identical blocks P and Q have mass m each. They are attached to two identical springs initially unstretched. Now the left spring (along with P) is compressed by A//2 and the right spring (along with Q ) is compressed by A . Both the blocks are released simultaneously. They collide perfectly inelastically. Initially time period of both the blocks was T . The energy of oscillation of the combined mass is

A block of mass 'm' collides perfectly inelastically with another identical block connected to a spring of of force constant 'K'. The amplitude of resulting SHM will be

Two blocks of mass M and m, are used to compress two different massless spring as shown. The left spring is compressed by 3 cm, while the right spring is compressed by an unknown amount.. The system is at rest, and all surfaces fixed and smooth. Which of the following statements are true?

In the figure, the block of mass m, attached to the spring of stiffness k is in correct with the completely elastic wall, and the compression in the spring is e. The spring is compressed further by e by displacing the block towards left and is then released. If the collision between the block and the wall is completely eleastic then the time period of oscillation of the block will be

A block is attached to a spring and is placed on a horizontal smooth surface as shown in which spring is unstretched. Now the spring is given an initial compression 2x_(0) an block is released from rest. Collision with the wall PQ are elastic. Find the time period of motion of the block: