A right body can be hinged about any point on the x-axis. When it is hinged such that the hinge is at x, the moment of inertia is given by
`l=2x^(2)-12x+27`
The x-coordinate of centre of mass is

A rigid body can be hinged about any point on the x-axis. When it is hinged such that the hinge is at x , the moment of interia is given by I = 2 x^(2) - 12 x + 27 The x-coordinate of centre of mass is.

A rod is placed along the line, y=2x with its centre at origin. The moment of inertia of the rod is maximum about.

Moment of inertia of a disc about an axis parallel to diameter and at a distance x from the centre of the disc is same as the moment of inertia of the disc about its centre axis. The radius of disc is R . The value of x is

The figure shows an isosceles triangle plate of mass M and base L . The angle at the apex is 90^@ . The apex lies at the origin and the base is parallel to X- axis. The moment of inertia of the plate about its base parallel to the x- axis is

The figure shows an isosceles triangle plate of mass M and base L . The angle at the apex is 90^@ . The apex lies at the origin and the base is parallel to X- axis. The moment of inertia of the plate about the y- axis is

Find the points of local maxima and minima of the function f given by f(x)= x^(3)-12x^(2)+36x+5 .

Find the equation of the curve passing through the point (0, -2) given that at any point (x , y) on the curve the product of the slope of its tangent and y coordinate of the point is equal to the x-coordinate of the point.

When a body is hinged at a point and a force is acting on the body in such a way that the line of action of force is at some distance from the hinged point, the body will start rotating about the hinged point. The angular acceleration of the body can be calculated by finding the torque of that force about the hinged point. A disc of mass m and radius R is hinged at point A at its bottom and is free to rotate in the vertical plane. A force of magnitude F is acting on the ring at top most point. Tangential acceleration of the centre of mass is

When a body is hinged at a point and a force is acting on the body in such a way that the line of action of force is at some distance from the hinged point, the body will start rotating about the hinged point. The angular acceleration of the body can be calculated by finding the torque of that force about the hinged point. A disc of mass m and radius R is hinged at point A at its bottom and is free to rotate in the vertical plane. A force of magnitude F is acting on the ring at top most point. Component of reaction at the hinge in the vertical direction is

When a body is hinged at a point and a force is acting on the body in such a way that the line of action of force is at some distance from the hinged point, the body will start rotating about the hinged point. The angular acceleration of the body can be calculated by finding the torque of that force about the hinged point. A disc of mass m and radius R is hinged at point A at its bottom and is free to rotate in the vertical plane. A force of magnitude F is acting on the ring at top most point. Component of reaction at the hinge in the horizontal direction is