A pulley-block arrangement is shown in the adjacent figure, if acceleration of `m_(1), m_(2)` and `m_(3)` are `a_(1) ,a_(2)` and `a_(3)` respectively, then relation between `a_(1),a_(2)` and `a_(3)` is ( All string and pulleys are ideal . )

Make the constraint relation between a_(1),a_(2) and a_(3)

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

In the pulley-block arrangement shown in figure , find the relation between a_(A),a_(B) and a_(C)

In the pulley-block arrangement shown in figure , find the relation between a_(A),a_(B) and a_(C)

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

Two blocks are arranged as shown in figure. Find the ratio of a_(1)//a_(2) . ( a_(1) is acceleration of m_(1) and a_(2) that of m_(2))

All the blocks are attached to an ideal rope which passes over an ideal pulley. If acceleration of blocks m_(1),m_(2),m_(3) and m_(4) and a_(1),a_(2),a_(3) and a_(4) respectively then choose the correct option.

A planet moving around sun sweeps area A_(1) in 2 days, A_(2) in 3 days and A_(3) in 6 days, then find the relation between A_(1),A_(2) and A_(3)

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

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_(3) at the moment spring PQ is cut is