O understand the definition and the meaning of moment of inertia; to be able to calculate the moments of inertia for a group of particles; to relate moment of inertia to kinetic energy. By now, you may be familiar with a set of equations describing rotational kinematics. One thing that you may have noticed was the similarity between translational and rotational formulas. Such similarity also exists in dynamics and in the work-energy domain. For a particle of mass m moving at a constant speed v, the kinetic energy is given by the formula K=12mv2. If we consider instead a rigid object of mass m rotating at a constant angular speed ω, the kinetic energy of such an object cannot be found by using the formula K=12mv2 directly, since different parts of the object have different linear speeds. However, they all have the same angular speed. It would be desirable to obtain a formula for kinetic energy of rotational motion that is similar to the one for translational motion; such a formula would include the term ω2 instead of v2. Such a formula can, indeed, be written: For rotational motion of a system of small particles or for a rigid object with continuous mass distribution, the kinetic energy can be written as K=12Iω2. Here, I is called the mom