Two masses m and M are attached with strings as shown in the figure, for the system to be in equilibrium, we must have

Two masses m and M are attached to the strings as shown in the figure. If the system is in equilibrium, then

Two masses m and M are attached with strings as shown. For the system to be in equilibrium we have.

Two masses m and M are attched with strings as shwon . If the system is in equilibrium then , tan theta

Two bodies of masses m and 4 m are attached with string as shown in the figure. The body of mass m hanging from a string of length l is executing oscillations of angular amplitude theta_(0) while the other body is at rest. The minimum coefficient of friction between the mass 4m and the horizontal surface should be

A man of mass m stands on a frame of mass M. He pulls on a light rope, which passes over a pulley. The other end of the rope is attached to the frame. For the system to be in equilibrium, what force must the man exert on the rope?

For the system shown in figure , to be in equilibrium , determine mass m .

A block of mass m is attached with two strings as shown in figure .Draw the free body diagram of the block.

Two block each of mass 'm' are attached with two elastic strings as shown in the figure. Masses of strings are negligible in comparison to block of mass 'm' density of material of each string is rho . The whole system is moving vertically upward with an acceleration a = g/2. It is in equilibrium with respect to elevator. Ratio of elongation in rod 1 to that of rod 2 will be

Two block each of mass 'm' are attached with two elastic strings as shown in the figure. Masses of strings are negligible in comparison to block of mass 'm' density of material of each string is rho . The whole system is moving vertically upward with an acceleration a = g/2. It is in equilibrium with respect to elevator. Ratio of PE stored in string-1 to string-2 in equilibrium is

The pulleys and strings shown in the figure are smooth and of negligible mass. For the system to remain in equilibrium, the angle theta should be