As shown in figure the cart mass `(m_1)` and block mass `(m_2)` (Assume ideal conditions, where ever necessary) Acceleration of the cart is `(xm_2g)/(4m_1+m_2)` then 'x' is

Two block of masses m_(1) and m_(2) are connected as shown in the figure. The acceleration of the block m_(2) is:

Two blocks of masses m_1 and m_2 are connected as shown in the figure. The acceleration of the block m_2 is :

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

Figure shows a block of mass 2m sliding on a block of mass m. Find the acceleration of each block . ( All surface are smoth )

A cart of mass M has a block of mass m in contact with it as shown in the figure-2.133. The coefficient of friction between the block and the cart is mu . What is the minimum acceleration of the cart so that the block m does not fall ?

In the diagram shown in figure wedge of mass M is stationary. Block of mass m=2 kg is slipping down. Force of friction on the wedge from ground is (g=10 m//s^(2))

Two blocks are placed at rest on a smooth fixed inclined place. A force F acts on block of mass m_1 and is parallel to the inclined plane as shown in figure. Both blocks move up the incline. Then (i) Draw free body diagram blocks of mass m_1 and blocks mass m_2 (ii) Find acceleration of blocks of mass m_1 and blocks mass m_2 (iii) Find normal reaction between the blocks of mass m_1 and m_2

Consider the system of masses and pulleys shown in fig. with massless string and fricitionless pulleys. (a) Give the necessary relation between masses m_(1) and m_(2) such that system is in equilibrium and does not move. (b) If m_(1)=6kg and m_(2)=8kg , calculate the magnitude and direction of the acceleration of m_(1) .

In the figure shown, the acceleration of block of mass m_(2) is 2m//s^(2) . The acceleration of m_(1) :