The centre of mass of a non uniform rod of length L, whose mass per unit length varies as `rho=(k.x^2)/(L)` where k is a constant and x is the distance of any point from one end is (from the same end)

The centre of mass of a non-uniform rod of length L whose mass per unit length lambda is proportional to x^2 , where x is distance from one end

Find coordinates of mass center of a non-uniform rod of length L whose linear mass density lambda varies as lambda=a+bx, where x is the distance from the lighter end.

The density of a non-uniform rod of length 1m is given by rho (x) = a (1 + bx^(2)) where a and b are constants and 0 le x le 1 . The centre of mass of the rod will be at

The density of a non-uniform rod of length 1m is given by rho (x) = a (1 + bx^(2)) where a and b are constants and 0 le x le 1 . The centre of mass of the rod will be at

The liner density of a rod of length 2m varies as lambda = (2 + 3x) kg/m, where x is distance from end A . The distance of a center of mass from the end B will be

The moment of inertia of a uniform thin rod of length L and mass M about an axis passing through a point at a distance of L//3 from one of its ends and perpendicular to the rod is

The density of a rod of length L varies as rho=A+Bx where x is the distance from the left end. Locate the centre of mass.

A rod of length L is of non uniform cross-section. Its mass per unit length varies linearly with distance from left end. Then its centre of mass from left end is at a distance. (Take linear density at left end=0).

Moment of inertia of a uniform rod of length L and mass M , about an axis passing through L//4 from one end and perpendicular to its length is

Moment of inertia of a uniform rod of length L and mass M , about an axis passing through L//4 from one end and perpendicular to its length is