A load of mass 100 gm increases the length of wire by 10 cm. If the system is kept in oscillation, its time period is `(g=10m//s^(2))`

A load of mass M is attached to the bottom of a spring of mass 'M //3' and spring constant 'K'. If the system is set into oscillation, the time period of oscillation is

The length of the seconds pendulums is first increased by 10 cm and then decreased by 5 cm. If the time period is determined in each case, find their ratio (Take g = 10 ms^(-2), pi^(2) ~= 10 )

A mass of 10 gm moving with a velocity of 100 cm / s strikes a pendulum bob of mass 10 gm . The two masses stick together. The maximum height reached by the system now is (g=10m//s^(2))

When a wire 2 m long and 0.05 cm^(2) in cross-section is stretched by a mass of 2 kg, it increases in length by 0.04 mm. Young's modulus of the material of the wire is (g=10ms^(-2))

Calculate the time period of oscillation of a uniform recctangular plate of length 96cm and breath 10cm when it is oscillating freely about one of its corners. (g=9.8ms^(-2)) .

A solid cube floats in water half immersed and h small vertical oscillations of time period pi/5 s. Find the mass (in kg) (Take g=10m/ s^(2) .

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))

A mild steel wire of length 1.0 m and cross-sectional are 0.5 xx 10^(-20)cm^(2) is streached, well within its elastic limit, horizontally between two pillars. A mass of 100 g is suspended from the mid point of the wire, calculate the depression at the mid point. g = 10ms^(-2), Y=2 xx 10^(11)Nm^(-2 .