[C] A corrugahorn is a corrugated tube which is spun around to make a sound. www ww .... Data: speed of sound = 344 m/s density of air = 1.29 [kg/m³] (1) Given such a tube with a length of 1.00 meter, what are the resonant frequencies for a tube of this length? (It's open at both ends).

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Chapter1: Units, Trigonometry. And Vectors
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[C] A corrugahorn is a corrugated tube which is spun around to make a sound.
Data: speed of sound = 344 m/s
density of air = 1.29 [kg/m³]
(1) Given such a tube with a length of 1.00 meter, what are the resonant frequencies for a tube of this
length? (It's open at both ends).
(2) Without the corrugations, the tube will not produce sound in the same way. If the corrugations in the
walls are spaced 8 mm apart, what is the frequency of a sound wave having a wavelength equal to the
spacing?
spacing a working candidate for that tone?
You can easily hear the tone when the tube is rotating, is this result from matching the ring
(3) Suppose tube, whose radius is 2 cm, is generating 0.1 Watts of wave energy. Treat this as being
emitted at the center of the tube, What would be the intensity of the wave
a) at the center of the tube,
b) at the end of the tube away from the hand.
c) 4 meters from the end of the tube.
Describe your approach to finding the intensity in each case.
(d) Calculate the amplitude of the wave at the center of the tube using the frequency from part 1.
(4) If the tube is being whirled around at 180 RPM, calculate the most Doppler shifted frequencies heard if
the frequency generated from the horn is your answer for part (1).
(5) Pellets falling on a thin membrane at a rate of 2 per second cause circular ripples to travel away from the
point of impact with a spacing of 1.8 cm between peaks. Calculate the wave speed in the membrane and, if
the power for the wave is 200 mW. calculate the intensity of the wave 5 cm from the source.
Bonus: If the pellets have a mass of 5.1 grams, if they rebound to half that height after collision.
Transcribed Image Text:[C] A corrugahorn is a corrugated tube which is spun around to make a sound. Data: speed of sound = 344 m/s density of air = 1.29 [kg/m³] (1) Given such a tube with a length of 1.00 meter, what are the resonant frequencies for a tube of this length? (It's open at both ends). (2) Without the corrugations, the tube will not produce sound in the same way. If the corrugations in the walls are spaced 8 mm apart, what is the frequency of a sound wave having a wavelength equal to the spacing? spacing a working candidate for that tone? You can easily hear the tone when the tube is rotating, is this result from matching the ring (3) Suppose tube, whose radius is 2 cm, is generating 0.1 Watts of wave energy. Treat this as being emitted at the center of the tube, What would be the intensity of the wave a) at the center of the tube, b) at the end of the tube away from the hand. c) 4 meters from the end of the tube. Describe your approach to finding the intensity in each case. (d) Calculate the amplitude of the wave at the center of the tube using the frequency from part 1. (4) If the tube is being whirled around at 180 RPM, calculate the most Doppler shifted frequencies heard if the frequency generated from the horn is your answer for part (1). (5) Pellets falling on a thin membrane at a rate of 2 per second cause circular ripples to travel away from the point of impact with a spacing of 1.8 cm between peaks. Calculate the wave speed in the membrane and, if the power for the wave is 200 mW. calculate the intensity of the wave 5 cm from the source. Bonus: If the pellets have a mass of 5.1 grams, if they rebound to half that height after collision.
(3) Suppose tube, whose radius is 2 cm, is generating 0.1 Watts of wave energy. Treat this as being
emitted at the center of the tube, What would be the intensity of the wave
a) at the center of the tube,
b) at the end of the tube away from the hand.
c) 4 meters from the end of the tube.
Describe your approach to finding the intensity in each case.
(d) Calculate the amplitude of the wave at the center of the tube using the frequency from part 1.
Transcribed Image Text:(3) Suppose tube, whose radius is 2 cm, is generating 0.1 Watts of wave energy. Treat this as being emitted at the center of the tube, What would be the intensity of the wave a) at the center of the tube, b) at the end of the tube away from the hand. c) 4 meters from the end of the tube. Describe your approach to finding the intensity in each case. (d) Calculate the amplitude of the wave at the center of the tube using the frequency from part 1.
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