A rope of length L and mass m hangs freely from the ceiling. The velocity of transverse wave as a function of position x from the bottom is proportional to

A rope of length L and mass m hangs freely from the ceiling. The velocity of transverse wave as a function of position x-along the rope is proportional to

A string of length L and mass M hangs freely from a fixed point . Calculate the velocity of the transverse wave along the string at any position. (b)Calculate time taken by a transverse pulse to traverse the string.

A heavy but uniform rope of lenth L is suspended from a ceiling. (a) Write the velocity of a transverse wave travelling on the string as a function of the distance from the lower end. (b) If the rope is given a sudden sideways jerk at the bottom, how long will it take for the pulse to reach teh celling ? (c ) A particle is dropped from the ceiling at the instant the bottom end is given the jerk where will the particle meet the pulse ?

There is a rod of length l and mass m . It is hinged at one end to the ceiling. The period of small oscillation is

A uniform rope of mass m and length L hangs from a celling. (a) Show that the speed of a transverse wave on the rope is a function of y , the distance from the lower end, and is given by t = 2sqrt(L//g) .

A uniform rope of mass 0.1 kg and length 2.45 m hangs from a ceiling. (a) Find the speed of transverse wave in the rope at a point 0.5 m distant from the lower end. (b) Calculate the time taken by a transverse wave to travel the full length of the rope.

A uniform rope of mass m hangs freely from a ceiling. A bird of mass M climbs up the rope with an acceleration a. The force exerted by the rope on the ceiling is

A uniform rope of length 12 m and mass 4 kg is hung vertically from a rigid support transverse wave pulse is produced at lower end. The speed of the wave pulse al x = 2.5 m from lower and will be kg=10 m/s)

A uniform rope of mass M=0.1kg and length L=10m hangs from the celling. [g=10m//s^(2)] :- (1)speed of transverse wave in the rope increases linearly from top to the bottom. (2)speed of the transverse wave in the rope decreases linearly from bottom to the top. (3)speed of the transverse wave in the rope remain constant along the length of the rope (4)time taken by the transverse wave to travel the full length of the rope is 2 sec.

A uniform rope of elngth l and mass m hangs vertically from a rigid support. A block of mass m is attached to the free end of the rope. A transverse pulse of wavelength lambda is produced at the lower end of the rope. The wavelength of the pulse, when it reaches the top of the rope. is alambda . Find a^(2)