Consider a vertical uniform string having mass per unit length lambda. A pulse is generated at the bottom. Acceleration of the pulse depends on x as

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

Two ropes of length l and l/2 and mass per unit length mu and mu//4 respectively are joined at B and hanged vertically with a heavy mass at its end C. A pulse is generated simultaneously at both ends A and C which travels along the ropes. Find the distance from the top at which pulses will cross each other.

A uniform rod of length L , has a mass per unit length lambda and area of cross section A . The elongation in the rod is l due to its own weight, if it suspended form the celing of a room. The Young's modulus of the rod is

Consider the three ropes of same length and same linear density as (shown in figure) suspended from the ceiling. A pulse is generated at the lowest point of the three ropes simultaneously. Choose the correct statements(s)

A wire of length L, is hanging vertically from a rigid support. If a transverse wave pulse is generated at the free end of wire then which of the following statement is wrong

The equation of a trevelling wave In a uniform string of mass per unit length unit length mu is given as y=Asin(omega-kx) .Find the total energy transferred through the origin in time interval from t = 0 to t=pi//12omega. (You can use the formula in instantaneous power if you know)

A load of mass M is attached to the free and of a uniform wire of mass m as shown in figure. If a transverse wave pulse is generated at the lower end of wire, find the ratio of velocity of wave at bottom end and at top end of wire

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)

A composition string is made up by joining two strings of different masses per unit length 1g/ m and 4 g/m. The composite string is under the same tension. A transverse wave pulse : Y = (6 mm) sin(5t + 40x), where it is in seconds and 'x' in meters, is sent along the lighter string towards the joint. The joint is at x = 0. The equation of the wave pulse reflected from the joint is

A vertical force of magnitude Facts at the top of a string of mass 'm' and length 'l'. A body of mass M hangs at the bottom of the string.