the linear density of a wire under tension t varies linearly from `mu_(1)` to `mu_(20`.Calculate the time that a pulse would need to pass one to the other.The length of the wire is l

A wire of length l is kept just taut horizontally between two walls.A mass m hanging from its mid point depresses it by delta .Calculte the time in which a pulse set up at one end will reach the other end . The mass of the wire per unit length of it is mu

A wave pulse is travelling on a string of linear mass density 1.0 g cm^(-1) under a tension of 1 kg wt. Calculate the time taken by the pulse to travel a distance of 50 cm on the string.Given g = 10 ms^(-2) .

A non-uniform wire of length l and mass M has a variable linear mass density given by mu = kx , where x is distance from one end of wire and k is a constant. Find the time taken by a pulse starting at one end to reach the other end when the tension in the wire is T .

A wire having a linear density 0.1 kg//m is kept under a tension of 490N. It is observed that it resonates at a frequency of 400 Hz. The next higher frequency is 450 Hz. Find the length of the wire.

One end of a string of length L is tied to the ceiling of a lift accelerating upwards with an acceleration 2. The other end o the string is freee. The linear mass density of the string varies linearly from 0 to lamda from bottom to top. The acceleration of a wave pulled through out the string is (pg)/(4) . Find p.

identical wires A amd B of different materials are hung from then ceilling of a room . The density of wire A is greater than the density of wire B but their lengths are same. Identical wave pulses are produced at the bottom of respective wires. The times taken by the pulse to reach the top is

A long wire PQR is made by joining two wires PQ and QR of equal radii PQ has length 4.8 m and mass 0.06 kg . QR has length 2.56m and mass 0.2 kg . The wire PQR is under a tension of 80N . A sinusoidal wave-pulse of amplitude 3.5cm is sent along the wire PQ from end P . No power is dissipated during the propagation of the wave-pulse. caculate, (a) the time taken by the wave-pulse to reach the other end R of the wire, and (b) the amplitude of the reflected and transmitted wave-pulse after the incident wave-pulse crosses the jjoint Q .