Assuming a sound velocity of 341, a tube 68.8 cm in length and open at both ends will have a natural frequency of...
Assuming a sound velocity of 341, a tube 68.8 cm in length and open at both...
Suppose we have a tube with adjustable length and open at both ends. The wavelength of the fundamental mode of vibration is lambda for a given length. Suppose now that the tube is adjusted to twice the given length. What happens to the wavelength of the fundamental mode? A. It is halved. B. It is doubles. C. It quadruples. D. Can’t tell without knowing the velocity of sound in air E. Can’t tell without knowing the frequency of vibration F....
A particular tube for a pipe organ is 4m long and open at both ends. The speed of sound is about 340m/s. Draw the first three harmonics and find the frequencies for the pressure wave view of sound. For each frequency, find another tube length that could also have this frequency as a harmonic. Now pretend the tube is closed at one end. Draw the first two harmonics and find the frequencies.
Calculate the length of a tube that has a fundamental frequency of 150.00 Hz, assuming that the tube is (a) closed at one end and (b) open at both ends. Note: Consider the air density as ρ = 1.20 kg / m3 and the speed of sound in air is v = 343 m / s.
Question 13: A tube with both ends open has fundamental frequency of 300 Hz. The second harmonic of this tube and the third harmonic of another tube which is closed at one end have the same frequency. What is the length of each of these tubes? (Speed of sound 343 m s, ignore end corrections)
If the fundamental frequency of a tube is 840 Hz, and the speed of sound is 343 m/s, determine the length of the tube (in m) for each of the following cases. If the fundamental frequency of a tube is 840 Hz, and the speed of sound is 343 m/s, determine the length of the tube (in m) for each of the following cases. (a) the tube is closed at one end m (b) the tube is open at both...
6. The standing wave is formed in a tube of length L which is open at both ends. The shape of this standing wave is shown in the picture, whereas the frequency of the 5th harmonic is 450 Hz. Speed of sound is 343 m/s. Find (a) length L of the tube, and (b) harmonic’s number n; (c) wavelength, and (d) frequency of the wave shown in the picture.
Length of Tube A hollow tube is placed in water so that it is open at one end. A tuning fork of frequency 365-Hz is brought to one end and the length of the tube adjusted so that the sound resonates at its fundamental inside the tube. If the length of the tube is 24 cm when the tuning fork resonates, what is the temperature in the physics laboratory? (We'll ignore the effects of the tube's diameter) Hint: Find the...
Length of Tube A hollow tube is placed in water so that it is open at one end. A tuning fork of frequency 365-Hz is brought to one end and the length of the tube adjusted so that the sound resonates at its fundamental inside the tube. If the length of the tube is 24 cm when the tuning fork resonates, what is the temperature in the physics laboratory? (We'll ignore the effects of the tube's diameter) Hint: Find the...
Length of Tube A hollow tube is placed in water so that it is open at one end. A tuning fork of frequency 365-Hz is brought to one end and the length of the tube adjusted so that the sound resonates at its fundamental inside the tube. If the length of the tube is 24 cm when the tuning fork resonates, what is the temperature in the physics laboratory? (We'll ignore the effects of the tube's diameter) Hint: Find the...
Length of Tube A hollow tube is placed in water so that it is open at one end. A tuning fork of frequency 365-Hz is brought to one end and the length of the tube adjusted so that the sound resonates at its fundamental inside the tube. If the length of the tube is 24 cm when the tuning fork resonates, what is the temperature in the physics laboratory? (We'll ignore the effects of the tube's diameter) Hint: Find the...