If the string is inextensible, determine the velocity u of each block in terms of v and `theta`.

(a) fig a: u=…
(b) fig.(b): u=….

In the arrangement of three block as shown in fig. the string is inextensible. If the direction of accelerations are as shown in the figure, then determine the constraint relation.

In the arrangement of three block as shown in fig. the string is inextensible. If the direction of accelerations are as shown in the figure, then determine the constraint relation.

If block A is moving horizontally with velocity v_(A) , then find the velocity of block B at the instant as shown in fig.

If block A is moving horizontally with velocity v_(A) , then find the velocity of block B at the instant as shown in fig.

Explain the terms in the formula v = u + at.

In the arrangement shown in the fig, block A is pulled so that it moves horizontally along the line AX with constant velocity u. Block B moves along the incline. Find the time taken by B to reach the pulley P if u = 1m//s . The string is inextensible.

In the arrangement shown in fig. The strings are light and inextensible. The surface over which blocks are placed is smooth. Find: (a) the acceleration of each block. (b) the tension in each string.

In the arrangement shown in fig. The strings are light and inextensible. The surface over which blocks are placed is smooth. Find: (a) the acceleration of each block. (b) the tension in each string.

A system of two blocks A and B are connected by an inextensible massless string as shown in Fig. The pulley is massless and frictionless. Initially, the system is at rest. A bullet of mass m moving with a velocity u as shown hits block If and gets embedded into it. The impulse imparted by tension force to the block of mass 3m is

A system of two blocks A and B are connected by an inextensible massless string as shown in Fig. The pulley is massless and frictionless. Initially, the system is at rest. A bullet of mass m moving with a velocity u as shown hits block If and gets embedded into it. The impulse imparted by tension force to the block of mass 3m is