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)` .

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) ]

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) .

The fundamental frequency of a 100 cm long sonometer wire is 330 Hz. Find out the velocity of transverse wave in the wire and the wavelength of the resulting sound waves in air . Given , velocity of sound in air = 330 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) .

A unifrom wire of length 1 m has mass 1 g . Under the tension 40 N . Find the velocity of sound wave ( transverse ) in the wire .

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)

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.

A hollow pipe of length 0. 8 m is closed at one end. At its open end a 0 . 5 m long uniform string is vibrating in its second harmonic and it resonates with the fundamental frequency of the pipe. It the tension in the wire is 50 N and the speed of sound is 320 m* s^(-1) . the mass of the string is