The mass at C is attached to the vertical pole AB by two wires. The assembly is rotating about AB at the constant angular speed `omega`. If the force in wire BC is twice the force in AC, determine the value of `omega`, see fig.

In the given figure, a smooth parabolic wire track lies in the xy -plane (vertical). The shape of track is defined by the equation y=x^(2) . A ring of mass m which can slide freely on the wire track, is placed at the position A (1,1) . The track is rotated with constant angular speed omega such that there is no relative slipping between the ring and the track. The value of omega is

ABC is a triangular frame made of a conducting wire and is right angled at B. Its side BC is vertical and AB is horizontal. The frame is placed in a uniform magnetic field B in vertically upward direction. The frame is rotated about its side BC with constant angular speed omega . Resistance of the entire frame is R. Neglect gravity. Length AB = L, BC = 2L . (a) Find the torque needed to keep the frame rotating with constant angular speed. (b) Find the potential difference between points A and C.

A package of mass m is placed inside a drum that rotates in the vertical plane at the constant angular speed omega=1.36 rad/s. If the package reaches the position theta=45^(@) before slipping determine the coefficient of friction between the package and drum. See fig.

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

A small wedge whose base is horizontal is fixed to a vertical rod as shown in fig . The sloping side of the weidgeis frictionless and the wedge is span with a constant angular speed omega about vertical axis as shown in the fig find the a. value of angular speed omega for which the block of mass m just does not slide down the wedge. b. normal reaction on the block by wedge when block does not slip relative to wedge.

A small ring P is threaded on a smooth wire bent in the form of a circle of radius a and centre O. The wire is rotating with constant angular speed omega about a vertical diameter xy, while the ring remains at rest relative to the wire at a distance (a)/(2) from xy. Then is equal to:

A copper wire of negligible mass, length l and corss-section A is kept on a smooth horizontal tabel with one end fiexed. A ball of mass m is attached to the other end. The wire and the ball are rotating with an angular velocity omega . If elongation in the wire is Deltal , obtain the expression for the Young's modulus.