An open pipe is suddenly closed at one end with the result that the frequency of third harmonic of the closed pipe is found to be higher by `100 Hz` then the fundamental frequency of the open pipe. The fundamental frequency of the open pipe is

If fundamental frequency of a given closed pipe is 50 Hz, then frequency for second overtone is…..

What are closed pipe and open pipe ?

Fundamental frequency of one closed pipe is 300 Hz. What will be the frequency of its second overtone ?

The second overtone of an open pipe has the same frequency as the first overtone of a closed pipe 2 m long. The length of the open pipe is

An open organ pipe filled with air has a fundamental frequency 500 Hz. The first harmonic of another organ pipe closed at one end and filled with carbon dioxide has the same frequency as that of the first harmonic of the open organ pipe. Calculate the length of each pipe. Assume that the velocity of sound in air and in carbondioxide to be 330 and 264 m/s respectively.

Fundamental frequency of one open pipe is equal to third harmonic of closed pipe of length 20 cm. Find length of open pipe.

Two narrow cylindrical pipes A and B have the same length. Pipe A is open at both ends and is filled with a monoatomic gas of molar mass M_(A) . Pipe B is open at one end and closed at the other end, and is filled with a diatomic gas of molar mass M_(B) . Both gases are at the same temperature. (a) If the frequency of the second harmonic of the fundamental mode in pipe A is equal to the frequency of the third harmonic of the fundamental mode in pipe B , determine the value of M_(B)//M_(B) . (b) Now the open end of pipe B is also closed (so that the pipe is closed at both ends). Find the ratio of the fundamental frequency in pipe A to that in pipe B .

For one closed pipe and one open pipe, frequencies of their first harmonics are same. Find ratio of their lengths.

When the open organ pipe resonates in its fundamental mode then at the centre of the pipe

A tube, closed at one end and containing air, produces, when excited, the fundamental note of frequency 512 Hz . If the tube is open at both ands the fundamental frequency that can be excited is (in Hz)