A rod has length `'l'` and mass per unit length linearly increases from `lamda` to `2 lamda` as shown in figure. Rod rotates with constant angular velocity `omega` in a gravity free space. Find the tension (in Newton) in the rod at its middle point. (take `omegal=2m//sec and lamda = 3 kg//m`)

A ring of mass m and radius R is being rotated about its axis with constant angular velocity omega in the gravity free space. Find tension in the ring.

A ring of radius 'r' and mass per unit length 'm' rotates with an angular velocity 'omega' in free space then :

A thin rod of mass m and length l is rotated in a horizontal plane about one of its ends with a constant angular speed omega in gravity free space.Then the tension at the midpoint of the rod is (3mlomega^2)/(p) .The value of p is?

As shown in the figure, a rod moves with v = 2 m/sec & rotates with omega = 2pi rad/sec. Find the point on the rod whose velocity is zero in this frame.

In the figure, a ball of mass m is tied with two strings of equal as shown. If the rod is rotated with angular velocity omega_(1) when

A uniform rod of mass m and length l rotates in a horizontal plane with an angular velocity omega about a vertical axis passing through one end. The tension in the rod at a distance x from the axis is

A midpoint of a thin uniform rod AB of mass m and length l is rigidly fixed to a rotation axle OO^' as shown in figure. The rod is set into rotation with a constant angular velocity omega . Find the resultant moment of the centrifugal forces of inertia relative to the point C in the reference frame fixed to the axle OO^' and to the end.

A uniform rod of length l is spinning with an angular velocity omega=2v/l while its centre of mass moves with a velocity v . Find the velocity of the end of the rod.

A uniform rod of length l and mass m is hung from, strings of equal length from a ceiling as shown in figure. Determine the tensions in the strings?

A rod of mass m and length l is connected with a light rod of length l . The composite rod is made to rotate with angular velocity omega as shown in the figure. Find the a. translational kinetic energy. b. rotational kinetic energy. c. total kinetic energy of rod.