If the length of an organ pipe closed at one end is 1 m and velocity of sound is `330 m//s`, then frequency for the second note is_______.

The length of a pipe, open at one end is 30 cm . If the velocity of sound in air is 330 m*s^(-1) , find out the fundamental frequency and the frequencies of the first two overtones formed due to vibration of the air column in the pipe .

A train is moving with a uniform speed of 33 m/s and an observer is approaching the train with the same speed. If the train blows a whistle of frequency 1000 Hz and the velocity of sound is 333 m/s, then the apparent frequency of the sound that the observer hears is

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) .

If the fundamental frequency emitted by a pipe closed at one end is 200 Hz, what is the frequency of the first overtone ?

The fundamental frequency of an air-filled open organ pipe is 500 Hz. The frequecny of the first harmonic in a carbon dioxide-filled organ pipe, closed at one end, is equal to the frequency of the first harmonic in the first pipe. Find the lengths of each of the organ pipes . The velocities of sound in air and carbon dioxide are 300 m*s^(-1) and 264 m*s^(-1) , respectively .

The length of an open organ pipe is twice the length of another closed organ pipe. The fundamental frequency of the open pipe is 100 Hz. The frequency of the third harmonic of the closed pipe is