A car is moving rightward with acceleration `a=gsqrt(k)m//s^(2)` . Find the value of k so that , rod maintains its orientation as shown in the figure. Neglect the friction and mass of the small rollers at A and B.

If a car is moving rightward with acceleration a = gsqrt(k) m//s rightward as shown in the figure. Find the value of k so that, rod maintains its orientation as shown in the figure. Neglect the friction and mass of the small roller at A and B.

In the figure shown neglecting friction and mass of pulley, what is the acceleration of mass B ?

In terms of masses m_(1),m_(2) and g, find the acceleration of both the blocks shown in Fig. Neglect all friction and masses of the pulley.

With what minimum acceleration mass M must be moved on frictionless surface so that m remains stick to it as shown in figure-2.171. The co-efficient of friction between M & m is mu :

Neglect friction. Find acceleration of m, 2 m and 3 m as shown in the figure. The wedge is find.

A block of mass 10 kg, moving with acceleration 2m//s^(2) on horizontal rough surface is shown in figure

Two block of masses m_(1) and m_(2) are in equilibrium. The block m_(2) hangs from a fixed smooth pulley by an inextensible string that is fitted with a light spring of stiffness k as shown in fig. Neglecting friction and mass of the string, find the acceleration of the bodies just after the string S is cut.

Two blocks A and B of mass 10 kg and 40 kg are connected by an ideal string as shown in the figure. Neglect the masses of the pulleys and effect of friction. (g = 10 m/s2) А B 45° Fixed 45°

Two blocks A and B of mass 10 kg and 40 kg are connected by an ideal string as shown in the figure. Neglect the masses of the pulleys and effect of friction. (g = 10 m/s2) A B 45° Fixed 45°

A vehicle is moving on a road with an acceleration a=20 m//s^(2) as shown in figure. The frictional coefficient between the block of mass (m) and the vehicle so that block is does not fall downward is (g=10m//s^(2))