A liquid of mass m set into oscillations in a U-tube of cross section A. Its time period recorded is T, where `T = 2pisqrt((l)/(2g))`, here l is the length of liquid column. If the liquid of same mass is set into oscillaions in U-tube of cross section `(A)/(16)` then determine time period of oscillation.

A liquid of mss m is set into oscillations in a U-tube of cross section A. Its time period recorded is T, where T=2pisqrt(l//2g) , here l is the length of liquid column. If the liquid of same mass is set into oscillations in U-tube of cross-section A/16 then determine time period of oscillation.

Find time period of liquid column of length l in the shown tube.

The time period of an oscillating body is given by T=2pisqrt((m)/(adg)) . What is the force equation for this body?

Time period T of a simple pendulum of length l is given by T = 2pisqrt((l)/(g)) . If the length is increased by 2% then an approximate change in the time period is

The time period of an oscillating simple pendulum is given as T=2pisqrt((l)/(g)) where l is its length and is about 1m having 1mm accuracy. Its time period is 2s . The time for 100 oscillations is measured by a stopwatch having least count 0.1s . The percentage error in the measurement of g is

A simple pendulum of length l_0 can perform simple harmonic oscillations with a time period T_0 . If the length of the pendulum is decreased to l_0/16 then the time time period of oscillation will become.

A spring elongated by length 'L' when a mass 'M' is suspended to it. Now a tiny mass 'm' is attached and then released, its time period of oscillation is -

A simple pendulum of length l is made to oscillate with an amplitude of 45 degrees. The acceleration due to gravity is g. Let T_(0) = 2pi sqrt(l//g) . The time period of oscillation of this pendulum will be -

A test tube of length l and area of cross-section A has some iron fillings of mass M. The test tube floats normally in a liquid of density rho with length x dipped in the liquid. A distribuing force makes the tube oscillate in the liquid. The time period of osciallation is given by (neglect the mass of the test tube)