The linear mass density of a thin rod AB of length L varies from A to B as `lambda (x) =lambda_0 (1 + x/L)`. Where x is the distance from A. If M is the mass of the rod then its moment of inertia about an axis passing through A and perpendicualr to the rod is :

The linear density of a thin rod of length 1m lies as lambda = (1+2x) , where x is the distance from its one end. Find the distance of its center of mass from this end.

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

Moment of inertia of a thin rod of mass m and length l about an axis passing through a point l/4 from one end and perpendicular to the rod is

Linear mss density (mass/length) of a rod depends on the distanec from one end (say A) as lamda_(x)=(alphax+beta) here alpha and beta are constants, find the moment of inertia of this rod about an axis passing through A and perpendicular to the rod. Length of the rod is l .

A particle mass m is attched to a thin uniform rod of length a at a distance of (a)/(4) from the mid-point C as shown in the figure. The mass of the rod is 4m The moment of inertia of the combined system about an axis passing through O and perpendicular to the rod is

Linear mass density of the two rods system, AC and CD is x. moment of inertia of two rods about an axis passing through AB is

A uniform rod of mass m is bent into the form of a semicircle of radius R. The moment of inertia of the rod about an axis passing through A and perpendicular to the plane of the paper is

A uniform rod of mass m is bent into the form of a semicircle of radius R. The moment of inertia of the rod about an axis passing through A and perpendicular to the plane of the paper is

Linear mass density of a rod AB(of length 10 m) varies with distance x from its end A as lambda = lambda_0x^3 ( lambda_0 is positive constant) . Distance of centre of mass of the rod , from end B is

Linear mass density of a rod AB ( of length 10 m) varied with distance x from its end A as lambda = lambda_0 x^3 ( lamda_0 is poitive constant). Distance of centre of mass the rod, form end B is