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

A block of mass m resting on a wedge of angle theta as shown in the figure. The wedge is given an acceleration a. What is the minimum value of a so that the mass m falls freely ?

Find the acceleration of the prism of mass M and that of the bar of mass m shown in figure.

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.

A block of mass m is at rest relative to the stationary wedge of mass M. The coefficient of friction between block and wedge is mu . The wedge is now pulled horizontally with acceleration a as shown in figure. Then the minimum magnitude of a for the friction between block and wedge to be zero is:

A block of mass m is at rest relative to the stationary wedge of mass M. The coefficient of friction between block and wedge is mu . The wedge is now pulled horizontally with acceleration a as shown in figure. Then the minimum magnitude of a for the friction between block and wedge to be zero is:

Find the acceleration of masses m_(1), m_(2) and m_(3) shown in figure-2.119 just after the string is cut at point A. [0,(1+(m_(1))/(m_(2)))g, g]

All surface are smooth. Find the acceleration of mass m relative to wedge when wedge is moving with acceleration 'a'

A rod of mass m is supported on a wedge of mass M shown in fig. Find the accelerations of rod and wedge in the arrangement. The friction between all contact surfaces in negligible.

A rod of mass m is supported on a wedge of mass M shown in fig. Find the accelerations of rod a and wedge A in the arrangment. The friction between all contact surfaces in negligible.