In given system `a_(1) and a_(2)` are the accelerations of blocks 1 and 2. Then constraint relation is

There is friction between the block A and B while ground is smooth. Magnitude of force F is increasing linearly with time, a_(1) and a_(2) are accelerations of block A and B. Which graph best represents acceleration a_(1) and a_(2) of block A and B respectively with time?

In each case m_(1) = 4 kg and m_(2) = 3 kg . If a_(1) and a_(2) and a_(3) are the respective acceleration of the block m_(1) in given situation, then

A ring of mass m connected through a string of length L with a block of mass M. If the ring is moving up with acceleration a_(m) and a_(M) is the acceleration of block. The relation between a_(m) and a_(M) is.

If pulleys shown in the diagram are smooth and massless and a_(1) and a_(2) are acceleration of blocks of mass 4 kg and 8 kg respectively, then -

A deuteron and an alpha -particle are placed in an electric field.The forces acting on them are F_(1) and F_(2) and their accelerations are a_(1) and a_(2) respectively. (i) F_(1) = F_(2) (ii) F_(1) != F_(2) (iii) a_(1) = a_(2) (iv) a_(1) != a_(2)

Find the relation between acceleration of blocks a_(1), a_(2) and a_(3) .

Figure shows two blocks each of mass m system is released from rest. If acceleration of blocks A and B at any instant (not initially) are a_(1) and a_(2) , respectively. Then

Find the relation between acceleration a_(1) and a_(2)

A block is attached with an ideal spring and string, and is in equilibrkum as shown in Figure. The acceleration of the block just after breaking the string is a_(1) and just after breaking the spring is a_(2) . Then

Three blocks A, B, and C of masses 3M, 2M , and M are suspended vertically with the help of spring PQ and TU, and a string RS as shown in fig. If the acceleration of blocks A, B and C is a_(1), a_(2) and a_(3) , respectively, then The value of acceleration a_(1) at the moment string RS is cut is