If the rod were translating as well as rotating, what will be its emf? Assume that the centre of mass has a velocity v and the rod is rotating with an angular velocity `omega` atout its centre of mass.

A rod is rotating with angular velocity omega about axis AB. Find costheta .

Find the instantneous axis of rotation of a rod length l when its end A moves with a velocity vecv_(A)=Vi and the rod rotates with an angular velocity vecomega=-v/(2l)hatk .

A smooth uniform rod of length L and mass M has two identical beads of negligible size each of mass m which can slide freely along the rod. Initially the two beads are at the centre of the rod and the system is rotating with an angular velocity omega_0 about an axis perpendicular to the rod and passing through the midpoint of the rod. There are no external forces. When the beads reach the ends of the rod, the angular velocity of the system is ......

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

In the above question if the coil rotates with a constant angular velocity omega , the EMF induced in it

A rod has a total charge Q uniformly distributed along its length L. If the rod rotates with angular velocity omega about its end, compute its magnetic moment.

A rod has a total charge Q uniformly distributed along its length L. If the rod rotates with angular velocity omega about its end, compute its magnetic moment.

A solid sphere of radius r and mass m rotates about an axis passing through its centre with angular velocity omega . Its K.E . Is

A uniform rod of mass M and length a lies on a smooth horizontal plane. A particle of mass m moving at a speed v perpendicular to the length of the rod strikes it at a distance a/4 from the centre and stops after the collision. Find a. the velocity of the cente of the rod and b. the angular velocity of the rod abut its centre just after the collision.

A disc of mass m has a charge Q distributed on its surface. It is rotating about an XX' with a angular velocity omega . The force acting on the disc is