If a wind instrument, such as a tuba, has a fundamental frequency of 54.0 Hz, what are its first three overtones (in Hz)? It is closed at one end. (The overtones of a real tuba are more complex than this example, because it is a tapered tube.)
first overtone _________Hz
second overtone _________Hz
third overtone ____________Hz
If a wind instrument, such as a tuba, has a fundamental frequency of 54.0 Hz, what...
If a wind instrument, such as a tuba, has a fundamental frequency of 37.5 Hz, what is its fifth overtone? It is closed at one end and the speed of sound is 330 m/s.
A tuba may be treated like a tube closed at one end. If a tuba has a fundamental frequency of 90.9 Hz, determine the first three overtones. Use 343 m/s as the speed of sound in air. first overtone How is the length of a tube closed at one end related to the resonant wavelengths that can be established in the tube? How are the frequency, wavelength, and speed of sound related? How are the harmonics related to the...
A tuba may be treated like a tube closed at one end. If a tuba has a fundamental frequency of 39.9 Hz, determine the first three overtones. Use 343 m/s as the speed of sound in air. Also, sketch a representation of the overtone described in parts a, b, and c. first overtone: Hz second overtone : Hz third overtone: Hz
What are the first three overtones of an alto clarinet that has a fundamental frequency of 90.0 Hz? Assume this instrument acts like a tube that is closed on one end, open on the other.
A musician in a concert hall is tuning her wind instrument. When she plays a short note she hears the echo of the note return from the opposite side of the 50.0 meter long auditorium 0.294 seconds later. Model the instrument as a tube closed at one end, if the instrument is properly tuned the note of the musician played would have a frequency of 233.082 Hz, but instead has a frequency of 226.513 Hz. This note is the first...
A musician in a concert hall is tuning her wind instrument. When she plays a short note she hears the echo of the note return from the opposite side of the 50.0 meter long auditorium 0.294 seconds later. Model the instrument as a tube closed at one end, if the instrument is properly tuned the note of the musician played would have a frequency of 233.082 Hz, but instead has a frequency of 226.513 Hz. This note is the first...
1.What energy in millijoules falls on a 0.89 cm diameter eardrum in 9 hours of exposure to a sound intensity level of 89.4 dB? 2.If a wind instrument, such as a tuba, has a fundamental frequency of 37.5 Hz, what is its fifth overtone? It is closed at one end and the speed of sound is 330 m/s.
The A string of a violin is 34 cm long between fixed points with a fundamental frequency of 440 Hz and a mass per unit length of 6.2×10−4 kg/m . What is the wave speed in the string? What is the tension in the string? What is the length of the tube of a simple wind instrument (say, an organ pipe) closed at one end whose fundamental is also 440 Hz if the speed of sound is 343m/s in air?...
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)
A closed (at one end) organ pipe has a fundamental frequency of 680 Hz. (a)What is the length of the pipe? (b)What is the wavelength of the fourth overtone?