The densities at points A and B are `rho_(0)` and `(3 rho_(0))/(2)`. Find the value of x on P-axis.

A planet is made of two materials of density rho_(1) and rho_(2) as shown in figure. The acceleration due to gravity at surface of planet is same as a depth 'R' . The ratio of (rho_(1))/(rho_(2)) is x/3 . Find the value of x .

The light cone is in equilibrium under the action of hydrostatic forces of two liquids of densities rho_(1) and rho_(2) . Find rho_(1)//rho_(2) . Find rho_(1) and rho_(2) .

The earth may be regarded as a spherically shaped uniform core of density rho_(1) and radius (R)/(2) surrounded by a uniform shell of thickness (R)/(2) and density rho_(2) . Find the ratio of (rho_(1))/(rho_(2)) if the value of acceleration due to gravity is the same at surface as at depth (R)/(2) from the surface.

A body of density rho floats with volume V_(1) of its total volume V immersed in a liquid of density rho_(1) and with the remainder of volume V_(2) immersed in another liquid of density rho_(2) where rho_(1)gtrho_(2) . Find the volume immersed in two liquids. ( V_(1) and V_(2) ).

Two discs have same mass and thickness. Their materials are of densities rho_(1) and rho_(2) . The ratio of their moment of inertia about central axis will be

Two circular discs A and B have equal masses and uniform thickness but have densities rho_(1) and rho_(2) such that rho_(1)gt rho_(2) . Their moments of inertia is

A thin rod AB of length a has variable mass per unit length rho_(0) (1 + (x)/(a)) where x is the distance measured from A and rho_(0) is a constant. Find the mass M of the rod.