A string `A B` of length `5 m` and linear mass denity `1 kg m^(-1)` is clamped at both the ends with a tension of 144 N. Find minimum frequency (in H z ) of transverse standing wave in string so that a node appears at a distance `3 m` from end `A`.

A string of length 0.5m and linear density 10^(-4) kg/m is stretched under a tension of 100 N. If the frequency of the vibration of the string is 4000 Hz, how many loops are formed on the string?

A string of length 0.4 m and mass 10^(-2) kg is clamped at its ends. The tension in the string is 1.6 N. When a pulse travels along the string the shape of the string is found to be the same at times t and t+trianglet . The value trianglet is

A sting of length 1m and linear mass density 0.01 kg//m is stretched to a tension of 100 N. When both ends of the string are fixed, the three lowest frequencies for standing wave are f_1, f_2 and f_3 . When only one end of the string is fixed, the three lowest frequencies for standing wave are n_1, n_2 and n_3 . Then,

A string of length L and mass M hangs freely from a fixed point. Then the velocity of transverse waves along the string at a distance x from the free end is

A transverse harmonic wave is propagating along a taut string. Tension in the string is 50 N and its linear mass density is 0.02 kg m^( –1) The string is driven by a 80 Hz oscillator tied to one end oscillating with an amplitude of 1mm. The other end of the string is terminated so that all the wave energy is absorbed and there is no reflection (a) Calculate the power of the oscillator. (b) The tension in the string is quadrupled. What is new amplitude of the wave if the power of the oscillator remains same? (c) Calculate the average energy of the wave on a 1.0 m long segment of the string.

A uniform string of length 20 m & mass 1 kg is hung vertically. Find the speed of wave at the mid point of the string :

A uniform string of length L and mass M is fixed at both end while it is subject to a tension T . It can vibrate at frequencies v given bby the formula (where, n=1,2,3,………..)

A 2.0m long string with a linear mass density of 5.2xx10^(-3) kg m^(-1) and tension 52N has both of its ends fixed. It vibrates in a standing wave patten with four antinodes. Frequency of the vibraion is :-

A string of mass per unit length "0.2 kg m"^(-1) and length 0.6 m is fixed at both ends such that it has a tension of 80 N. If the string is vibrating in its second overtone mode, then the frequency of the string is