The kinetic energy K of a rotating body depends on its moment of inertia I and its angular speed `omega`. Assuming the relation to be `K=kI^(alpha) omega^b` where k is a dimensionless constatnt, find a and b. Moment of inertia of a spere about its diameter is `2/5Mr^2`.

Kinetic energy of a body is 4j and its moment of inertia is 2kg m^(2) , then angular momentum is

The kinetic energy of a body ia 4 joule and its moment of inertia is 2" kg m"^(2) . Angular momentum is

The K.E. of a body is 3 joule and its moment of inertia is "6 kg m"^(2) . Then its angular momentum will be

The rotational kinetic energy of a rigid body of moment of inertia 5 kg-m^(2) is 10 joules. The angular momentum about the axis of rotation would be -

If the angular velocity of a rotating rigid body is increased then its moment of inertia about that axis

The moment of inertia of a rigid body in terms of its angular momentum L and kinetic energy K is

The moment of inertia of a uniform rod about a perpendicular axis passing through one end is I_(1) . The same rod is bent into a ring and its moment of inertia about a diameter is I_(2) . Then I_(1)//I_(2) is

The relation between the torque tau and angular momentum L of a body of moment of inertia I rotating with angular velocity omega is

Find the value of a and b in the following cases : (a) The velocity v of the ball falling freely under gravity is proportional to g^(a) h^(b) , where g is the acceleration due to gravity, h is the height from which the ball is dropped. (b) The kinetic energy K of a rotating body is proportional to I^(a) omega^(b) where I is the moment if inertia and omega is the angular speed. (c ) The time-period T of spring pendulum is proportiona to m^(a) k^(b) , where m is the mass of block attached to the spring and k is the spring constant. The speed of sound v in a gaseous medium is proportional to P^(a) rho^(b) , where P is the pressure and rho is the density of medium.