A uniform rope of mass of 0.1 kg and length 2.45 m hangs from the ceiling. The time taken by a transverse wave to travel the full length of rope is n sec. Then n

A unifrom rope of mass 0.1kg and length 2.45 m hangs from a rigid support. The time taken by the transverse wave formed in the rope to travel through the full length of the rope is (Assume g= =9.8 m//s^2 )

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 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 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 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 uniform rope of mass M length L hangs vertically from the ceiling, with lower end free. A distbance on the rope trvelling upwards starting from the lower end has a velocity v. At a point P at distance x from the lower end.

Let is consider the following diagram in which a block of mass M is being supported by a uniform rope of mass 1 kg and length 10 metre, a pulse is created at the bottom of the rope and it reaches the top. In column I the value of M in kg is given and in column II time (in sec) after which the pulse reaches the top is given. Match them

A thick uniform rope of length L is hanging from a rigid support. A transverse wave of wavelength lamda_(0) is set up in the middle of the rope. The wavelength of the wave as it reaches the top most point is

A uniform wire of length 20 m and weighing 5 kg hangs vertically. If g=10 m s^(-2) , then the speed of transverse waves in the middle of the wire is

A uniform rope with length L and mass m is held at one end and whirled in a horizontal circle with angular velocity omega . You can ignor the force of gravity on the rope. Find the time required for a transverse wave to travel from one end of the rope to the other. Hint: int (dx)/(sqrt(a^(2) - (x^(2)))) = sin^(-1)((x)/(a))