In the instant shown in the diagram the board is moving up (vertically) with velocity `v`. The drum winds up at a constant rate `omega`. If the radius of the drum is `R` and the board always remains horizontal, find the value of velocity in terms of `R, theta, omega`.

In the diagram 100kg block is moving up with constant velocity, then find out the tension at point P :

In the block moves up with constant velocity v m/s. Find F

If block A is moving horizontally with velocity v_(A) , then find the velocity of block B at the instant as shown in fig.

In the circuit shown in Fig. Sliding contact is moving with uniform velocity towards right. Its value at some instance is 12 (Omega) . The current in the circuit at this instant of time will be

In the circuit shown in Fig. Sliding contact is moving with uniform velocity towards right. Its value at some instance is 12 (Omega) . The current in the circuit at this instant of time will be

In the system shown, the block A is moving down eith velocity v_(1) and C is moving up with velocity v_(3) . Express velocity of the block B in terms of velocities of the blocks a and C.

A rod of mass m and length l is rotating about a fixed point in the ceiling with an angular velocity omega as shown in the figure. The rod maintains a constant angle theta with the vertical. What will be the horizontal component of angular momentum of the rod about the point of suspension in terms of m , omega , l and theta .

A stone tied to a string of length l is whirled in a horizontal circle at a constant angular speed omega in a circle of radius r. If the string makes an angle theta with vertical then the tension in the string is :

A uniform rod of maass m and length L is placed on the fixed cylindrical surface of radius R at an small angular position theta from the vertical (vertical means line joining centre and vertex of the cylindrical path) as shown in the figure and released from rest. Find the angular velocity omega of the rod at the instant when it crosses the horizontal position (Assume that when rod comes at horizontal position its mid point and vertex of the circular surface coincide). Friction is sufficient to prevent any slipping.

A metallic ring of radius r with a uniform metallic spoke of negligible mass and length r is rotated about its axis with angular velocity omega in a perpendicular uniform magnetic field B as shown in Fig. 3.163. The central end of the spoke is connected to the rim of the wheel through a resistor R as shown. The resistor does not rotate, its one end is always at the center of the ring and the other end is always in as shown is needed to maintain constant angular velocity of the wheel. F is equal to (the ring and the spoke has zero resistance)