Consider a situation as shown in the figure. The system is released from rest. When the block of mass `m` has falled a distance `L`, its speed becomes `(sqrt(gL))/(3)`. Find the friction coefficient `mu`.

Consider the situation as shown in the figure. The system is released from rest. Find the speed of m when it has traveled a distance d on a rough surface.

Consider the situatioin shown in figure. The system is released from rest and the block of mass 1.0 kg is found to have a speed 0.3 m/s ater it has descended thrugh a distance of 1 m. find the coefficient of kinetic friction between the block and the table.

Consider the situatioin shown in figure. The system is released from rest and the block of mass 1.0 kg is found to have a speed 0.3 m/s ater it has descended thrugh a distance of 1 m. find the coefficient of kinetic friction between the block and the table.

The system shown in the figure is released from rest. At the instant when mass M has fallen through a distance h, the velocity of m will be

The system shown in the figure is released from rest. At the instant when mass M has fallen through a distance h, the velocity of m will be

In the figure shown, the system is released frrom rest. Find the velocity of block A when block B has fallen a distance l . Assume all pulleys to be massless and frictionless.

In the system shown in figure, the block A is released from rest. Find Tension in the string.

Two blocks asre connected by a string as shown in figure. They are released from rest. Show that after they moved a distance L, their common speed is given by sqrt((2(m_(2)-mu m_(1))gL)/((m_(1)+m_(2)))) where mu is the coefficient of friction.