Linear mass density of rod varies as `lambda = lambda_0(1-(x^2/l^2))`. Find COM of rod.

A non-uniform thin rod of length L is palced along X-axis so that one of its ends is at the origin. The linear mass density of rod is lambda = lambda_(0)x . The centre of mass of rod divides the length of the rod in the ratio:

A non–uniform thin rod of length L is placed along x-axis as such its one of ends at the origin. The linear mass density of rod is lambda=lambda_(0)x . The distance of centre of mass of rod from the origin is :

A rod of length L is placed along the x-axis between x=0 and x=L. The linear mass density is lambda such that lambda=a+bx . Find the mass of the rod.

The linear mass density lambda of a rod AB is given by lambda =aplha+betaxkg/m taking O as origin. Find the location of the centre of mass from the end A?

The adjacent figure shows a non-uniform metre stick AB having the linear mass density variation lambda = lambda_(0) x , where lambda_(0) is a constant and x is the distance from end A, placed on a smooth horizontal surface. In the first experiment, the rod is pivoted at A and force F is applied perpendicular to the rod at the other end B and in the second experiment, the rod is pivoted at B and the force is applied perpendicular to the rod at the end A. If in the first case angular acceleration is alpha_(A) and in the second case it is alpha_(B) then

If the linear density of a rod of length L varies as lambda = A+Bx , find the position of its centre of mass .

A rod of length 2m has uniform cross- section but linear mass density varies as lambda=(1+x)kg/m .It is placed as shown in figure.The moment of inertia of rod about an axis passing through O and perpendicular to rod is (x is in metre )

The linear mass density of a rod of length 2L varies with distance (x) from center as lambda=lambda_(0)(1+(x)/(L)) .The distance of COM from center is nL.Then n is

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 :