Two cars having masses `m_1 and m_2` move in circles of radii `r_1 and r_2` respectively. If they complete the circle is equal time the ratio of their angular speeds is `omega_1/omega_2` is

Figure shows two cylinders of radii r_1 and r_2 having moments of inertia I_1 and I_2 about their respective axes. Initially the cylinders rotate about their axes with angular speed omega_1 and omega_2 as shown in the figure. The cylinders are moved closer to touch each other keeping the axes parallel. The cylinders first slip over each other at the contact but the slipping finally ceases due to the friction between them. Find the angular speeds of the cylinders after the slipping ceases.

If same force is acting on two masses m_1 and m_2 and the accelerations of two bodies are a_1 and a_2 respectively, then

If two circular discs A and B are of same mass but of radii r and 2r respectively, then the moment of inertia of A is:

The circles having radii r_1a n dr_2 intersect orthogonally. The length of their common chord is

Two discs of moments of inertia l_(1) and I_(2) about their respective axes (normal to the disc and passing through the centre), and rotating with angular speed omega_(1) and omega_(2) are brought into contact face to face with their axes of rotation coincident, (i) What is the angular speed the two-disc system? (i) Show that the kinetic energy of the combined system is less than the sum of the initial kinetic energies of the two discs. How do you account for this loss in energy? Take omega_(1)ne omega_(2) .

Two steel wires of lengths 1 m and 2 m have diameters 1 mm and 2mm respectively . If they are stretched by force of 40 N and 80 N respectively, find the ratio of their elongations.

Two masses M_(1) and m_(2) are experiencing the same force where m_(1)ltm_(2) the ratio of their acceleration (a_(1))/(a_(2)) is