From a uniform sphere of mass `M` and radius `R` a cavity of diameter `R` is created as shown. Find the ratio of moment of inertia of the sphere left about `"AA"'` and `BB'`.

Four rings each of mass M and radius R are arranged as shown in the figure. The moment of inertia of the system about YY' will be

Moment of inertia of a circular wire of mass M and radius R about its diameter is

A particle of mass m is placed at a distance of 4R from the centre of a huge uniform sphere of mass M and radius R . A spherical cavity of diameter R is made in the sphere as shown in the figure. If the gravitational interaction potential energy of the system of mass m and the remaining sphere after making the cavity is (lambdaGMm)/(28R) . Find the value of lambda

Three solid sphere of mass M and radius R are placed in contact as shown in figure. Find the potential energy of the system ?

The moment of ineria (I) of a sphere of radius R and mass M is given by

Find the moment of inertia of a uniform ring of mass M and radius R about a diameter.

Three identical rings of masses m each and radius r are kept in contact as shown in Fig. Find the moment of inertia of the system about a common tangent.

The figure represents a solid uniform sphere of mass M and radius R . A spherical cavity of radius r is at a distance a from the centre of the sphere. The gravitational field inside the cavity is

A system of uniform rod of mass m and length 2R and a uniform disc of m and radius R are as shown in the figure. The moment of inertia of the system about the axis OO^' (perpendicular to plane of disc) will be

A solid sphere of mass m and radius R is rolling without slipping as shown in figure. Find angular momentum of the sphere about z-axis.