What is the length of a tube with specific frequencies and speed of sound?
Calculation of the Length of the Tube
Length Calculation: The length of the tube is found by using the formula for the speed of a wave which involves the fundamental frequency. We substitute the given values into the equation and find that the length of the tube is approximately 1.03 meters.
Explanation
To answer this question, we first need to understand the concept of fundamental frequency and overtones in physics. Fundamental frequency, also known as the first harmonic, is the lowest frequency in the harmonic sequence. Overtones, on the other hand, are the higher frequencies. In a tube, the first overtone, or the second harmonic, is exactly twice the fundamental frequency.
From the question, the fundamental frequency is 164 Hz and the first overtone is 328 Hz. So, that's consistent. Now, we know that the speed of a wave (v) is equal to its frequency (f) times its wavelength (λ), described as: v = f * λ. In a tube where the wave can bounce back and forth, the length of the tube is essentially half the wavelength (λ/2).
If we rearrange the equation to solve for length (L), we get L = v / (2f). Substituting the given values in, we calculate the length as L = 338 m/s / (2*164 Hz) = 1.03 m.
What is the length (in meters) of a tube that has a fundamental frequency of 164 Hz and a first overtone of 328 Hz if the speed of sound is 338 m/s? Final answer: The length of the tube is found by using the formula for the speed of a wave which also involves the fundamental frequency. Substituting given values into the rearranged equation provides the length of the tube which is approximately 1.03 meters.