A disc of mass 'm' is suspended at a point R/2 above its centre. Find its period of oscillation.

Compound pendulum are made of : (a) A rod of length l suspended through a point located at distance l // 4 from centre of rod. (b) A ring of mass m and radius r suspended through a point on its periphery. (c) A uniform square plate of edge a suspended through a corner. (d) A uniform disc of mass m and radius r suspeneded through a point r//2 away from the centre. Find the time period in each case.

When a mass M is suspended from a spring, its period of oscillation is 2 second. If a mass 4 M is suspended from the same spring, then its period of oscillation will be

A spring is stretched by 0.20 m , when a mass of 0.50 kg is suspended. When a mass of 0.25 kg is suspended, then its period of oscillation will be (g = 10 m//s^(2))

Find time period of uniform disc of mass m and radius r suspended through point r//2 away from centre, oscillating in a plane parallel to its plane.

Find time period of uniform disc of mass m and radius r suspended through point r//2 away from centre, oscillating in a plane parallel to its plane.

Find the time period of small oscillations of the following systems. (a) A uniform rod of mass m and length L is suspended through a pin hole at distance L//4 from top as shown. (b) A ring of mass m and radius r suspended through a point on its periphery. (c) A uniform disc of mass m and radius r suspended through a point r//2 away from centre. (d) A uniform square plate of edge a suspended through a corner.

A uniform rod of mass m and length l is suspended about its end. Time period of small angular oscillations is

A uniform rod of mass m and length l is suspended about its end. Time period of small angular oscillations is

A circular disc of mass 12 kg is suspended by a wire attached to its centre. The wire is twisted by rotating the disc and then released, so that the time period of torsional oscillation is 2 s. If the radius of the disc is 10 cm, then calculate the torsional spring constant of the wire.