Fig. shows a block of mass `m_(1)` resting on a smooth surface. It is connected to a mass `m_(2)` by a string passing over a massless and frictionaless pulleys `m_(2) gt m_(1)`. The acceleration of the hanging mass `m_(2)` is `:`

Two masses m and m (mgtm) are connected by massless flexible and inextensible string passed over massless and frictionless pulley. The acceleration of centre of mass is

A block of mass m_(1) =2 kg on a smooth inclined planeat angle 30^(@) is connected to a second block of mass m_(2) =3kg by a cord passing over a frictionless pulley as shown in figure. The acceleration of each block is - (Assume g = 10 m//sec^(2) )

Two masses m_(1) and m_(2) ( m_(2) gt m_(1)) are hanging vertically over frictionless pulley. The acceleration of the two masses is :

Two masses m_(1) and m_(2) are attached to a string which passes over a frictionless smooth pulley. When m_(1)=10kg,m_(2)=6kg , the acceleration of masses is

Two blocks of masses m_1 = 4 kg and m_2 = 2 kg are connected to the ends of a string which passes over a massless, frictionless pulley. The total downwards thrust on the pulley is nearly

Two particles of masses m and M(Mgtm) are connected by a cord that passes over a massless, frictionless pulley. The tension T in the string and the acceleration a of the particles is

Two blocks of masses m_(1) and m_(2)(m_(1) gt m_(2)) connected by a massless string passing over a frictionless pulley Magnitude of acceleration of blocks would be

A block of mass M placed on a frictionless horizontal table is pulled by another block of mass m hanging vertically by a massless string passing over a frictionless pulley. The tension in the string is :

Find the acceleration of masses m_(1) and m_(2) moving down the smooth incline plane. The string and the pulley are masseless and frictionless.

A block of mass m_(1) lies on a smooth horizontal table and is connected to another freely hanging block of mass m_(2) by a light inextensible string passing over a smooth fixed pulley situated at the edge o fthe table. Initially the system is at rest with m_(1) a distance d from the pulley. Then the time taken for m_(1) to reach the pulley is.