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 -

Two masses are connected by a string which passes over a pulley acceleration upward at a rate A shown. If a_(1) and a_(2) be the accelerations of bodies 1 and 2 respectively then,

In the system shown in the diagram all surfaces are smooth, pulley and strings are ideal. If vec( a_(A)) and vec( a_(B)) are the accelerations of the two blocks, then just after the system is released from rest, then choose correct statement(s) :

In the arrangement shown in fig., all pulleys are smooth and massless. When the system is released from the rest, acceleration of block 2 and 3 relative to 1 are 1 ms^(-2) downwards and 5ms^(-2) downwards, respectively. Acceleration of block 3 relative to 4 is zero. Find the absoulte acceleration of block 4.

In the arrangement shown in fig., all pulleys are smooth and massless. When the system is released from the rest, acceleration of block 2 and 3 relative to 1 are 1 ms^(-2) downwards and 5ms^(-2) downwards, respectively. Acceleration of block 3 relative to 4 is zero. Find the absolute acceleration of block 1.

In the arrangement shown in fig., all pulleys are smooth and massless. When the system is released from the rest, acceleration of block 2 and 3 relative to 1 are 1 ms^(-2) downwards and 5ms^(-2) downwards, respectively. Acceleration of block 3 relative to 4 is zero. Find the absoulte acceleration of block 2.

In the arrangement shown in fig., all pulleys are smooth and massless. When the system is released from the rest, acceleration of block 2 and 3 relative to 1 are 1 ms^(-2) downwards and 5ms^(-2) downwards, respectively. Acceleration of block 3 relative to 4 is zero. Find the absoulte acceleration of block 3.

In the diagram shown in figure, both pulleys and strings are massless. The acceleration of 2 kg block is

In the adjacent figure, all the pulleys are frictioniess and massless, all the stringes are also massless. The relation between a_(1),a_(2) and a_(3) is (where a_(1),a_(2) and a_(3) are the acceleration of masses m_(1),m_(2) and m_(3) respectively in the direction as shown in the figure)

In the shown diagram m_(1)=m_(2)=4kg and m_(3)=2 kg . Coefficient of friction between m_(1) and m_(2) is 0.5. The mass m_(1) is given a velocity v and it just stops at the other end of the mass m_(1) in 1 sec. Let a_(1) and a_(2) and a_(3) be the acceleration m_(1),m_(2)and m_(3) respectively, then :