If system is in equilibrium then find relation between `m_(1)` and `m_(2)`

In the figure-2.219 shown, if the system is in equilibrium. Find the relation in m_(1) and m_(2) forthe case (i) if the bar is just going to slide and (ii) if box is just going to slide.

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) .

PQR is a rigid equilateral triangle frame of a side length L . Forces F_1, F_2 and F_3 are acting along PQ, QR, PR . If the system is in rotational equilibrium find the relation between the forces.

In the fig, find the acceleration of m_(1) and m_(2)

In the fig, find the acceleration of m_(1) and m_(2) .

A two block system is shown in figure . We shall draw complete free body diagram and find normal reaction between m_(1) and m_(2) and between m_(2) and ground .

The system is in equilibrium and at rest. Now mass m_(1) is removed from m_(2) . Find the time period and amplituded of resultant motion. Spring constant is K .

The system shown in fig is in equilibrium . Masses m_(1) and m_(2) are 2kg and 8kg, Respectively. Spring constants k_(1) and k_(2) are 50Nm^(-1) and 70Nm^(-1) , respectively. If the compression in second spring is 0.5m. What is the compression in first spring?

When force F applied on m_(2) and there is no friction between m_(1) and surface and the coefficient of friction between m_(1) and m_(2) is mu… What should be the minimum value of F so that there is no relative motion between m_(1) and m_(2)