Determine the frequencies of first three overtones produced in a 50 cm long pipe open at both ends .
[Velocity of sound in air =` 330 m*s^(-1)` ]

Find out the frequency of the first overtone emitted by a 1 . 25 m long organ pipe closed at one end. Given , velocity of sound in air = 320 m * s^(-1)

Find out the fundamental frequency of a 125 cm long organ pipe closed at one end . Given, velocity of sound in air = 350 m*s^(-1) .

The frequencies of the fundamentals produced by a 200 cm long pipe open at both ends and a 25 cm long sonometer wire are the same. The mass of 1 cm length of the wire is 1 g . Calculate the tension produced in the wire . Velocity of sound in air is 330 m*s^(-1) .

Find out the frequencies of the fundamental and its nearest harmonic emitted by a 1 m long closed organ pipe. Given, velocity of sound in air 332 m * s^(-1) .

A tuning fork of frequency 256 Hz is held over the open upper end of a 200 cm long vertical pipe filled with water and the water is slowly darined out through the bottom end of the pipe. Determine the positions of the water level at the time of the first and the second resonances. Neglect the end error. Velocity of sound in air = 320 m* s^(-1) .

A wire of length 25 cm and mass 2 . 5 g is stretched with a fixed tension. The length of a pipe closed at one end is 40 cm . During vibrations, the first overtone of the wire produces 8 beats per second with the fundamental emitted by the pipe . The number of beats reduces with the decrease in tension in the wire. If the velocity of sound in air is 320 m*s^(-1) , find the tension in the wire.

The length of an organ pipe closed at one end is 90 cm . Find out the frequency of the harmonic next to the fundamental . Velocity of sound in air = 300 m* s^(-1) .