The blocks are on frictionless inclined ramp and connected by a massless cord. The cord passes over an ideal pully. `[g=10m//s^(2)]`

What value of M would keep the system rest.

The blocks are on frictionless inclined ramp and connected by a massless cord. The cord passes over an ideal pully. [g=10m//s^(2)] When to 10 kg block slides down the ramp with acceleration of 2m//s^(2) tension in the crod is closest to :-

The blocks are on frictionless inclined ramp and connected by a massless cord. The cord passes over an ideal pully. [g=10m//s^(2)] When set free, the 10n kg block slides down the ramp with acceleration of 2m//s^(2) mass M is closest to

Figure 5-20 shows a block S (the sliding block) with mass M = 3.3 kg. The block is free to move along a horizontal frictionless surface and connected, by a cord that wraps over a frictionless pulley, to a second block H (the hanging block), with mass m = 2.1 kg. The cord and pulley have negligible masses compared to the blocks (they are "massless"). The hanging block H falls as the sliding block S accelerates to the right. Find (a) the acceleration of block S, (b) the acceleration of block H, and ( c ) the tension in the cord. Figure 5.20 A block S of mass M is connected to a block H of mass m by a cord that wraps over a pulley.

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

Two blocks of mass m_(1) and m_(2) , resting on a frictionless table, are connected by a stretched spring and then released -

A block of mass m_(1)=3.70 kg on a frictionless plane inclined at angle 30.0^(@) is connected by a cord over a massless, frictionless pulley to a second block of mass m_(2)=2.30 kg (see Fig. 5-32). (a) What is the magnitude of the acceleration of each block? (b) What is the direction of the acceleration of the hanging block ? (c) What is the tension in the cord?

In the system shown all the surfaces are frictionless while pulley and string are massless. The mass of block A is 2m and that of block B is m. The acceleration of block B immediately after system is released from rest is

Two blocks of mass M and 2M are connected to the two ends of a light, inextensible string passing over an ideal pulley as shown in figure. The system is released from rest. (a) One second after the system is released, a particle of mass M hits the block of mass M and sticks to it. The particle hits the block with a speed of 10 m/s while travelling downward. Find the total distance travelled by block of mass 2M after it is released. (b) One second after the system is released, a particle of mass 2M hits the block of mass M and sticks to it. The particle hits the block with a speed of 10 m/s while travelling in upward direction. Find distance travelled by the block of mass 2M after it is released to the time it comes to rest for the first time (g = 10 m//s)^(2)