A flute can be modeled as an open-open tube. My flute is L = 0.5969 m from %3D mouthpiece (one open end) and the end (the other open end). Assume 20 °C. 3 mode when the flute is open to a) What is the frequency of the m = atmosphere only at the two open ends? b) I lift a key that creates a hole 2L/5 from the open end. Recall that this hole opens to atmospheric pressure, as do the open ends. i. Draw the lowest-frequency mode that meets the boundary conditions at the two open ends and this new hole at 2L/5. ii. Calculate the frequency and wavelength of this mode.

A flute can be modeled as an open-open tube. My flute is L = 0.5969 m from %3D mouthpiece (one open end) and the end (the other open end). Assume 20 °C. 3 mode when the flute is open to a) What is the frequency of the m = atmosphere only at the two open ends? b) I lift a key that creates a hole 2L/5 from the open end. Recall that this hole opens to atmospheric pressure, as do the open ends. i. Draw the lowest-frequency mode that meets the boundary conditions at the two open ends and this new hole at 2L/5. ii. Calculate the frequency and wavelength of this mode.

University Physics Volume 1

18th Edition

ISBN:9781938168277

Author:William Moebs, Samuel J. Ling, Jeff Sanny

Publisher:William Moebs, Samuel J. Ling, Jeff Sanny

Chapter15: Oscillations

Section: Chapter Questions

Problem 27P: Each piston of an engine makes a sharp sound every other revolution of the engine. (a) How fast is a...

See similar textbooks

Similar questions

A student holds an inexpensive sonic range finder and uses the range finder to find the distance to the wall. The sonic range finder emits a sound wave. The sound wave reflects off the wall and returns to the range finder. The round trip takes 0.012 s. The range finder was calibrated for use at room temperature T=20C , but the temperature in the room is actually T=23C . Assuming that the timing mechanism is perfect, what percentage of error can the student expect due to the calibration?
In the short story The Pit and the Pendulum by 19th-century American horror writer Edgar Allen Poe, a man is tied to a table directly below a swinging pendulum that is slowly lowered toward him. The bob of the pendulum is a 1-ft steel scythe connected to a 30-ft brass rod. When the man first sees the pendulum, the pivot is roughly 1 ft above the scythe so that a 29-ft length of the brass rod oscillates above the pivot (Fig. P16.39A). The man escapes when the pivot is near the end of the brass rod (Fig. P16.39B). a. Model the pendulum as a particle of mass ms 5 2 kg attached to a rod of mass mr 5 160 kg. Find the pendulums center of mass and rotational inertia around an axis through its center of mass. (Check your answers by finding the center of mass and rotational inertia of just the brass rod.) b. What is the initial period of the pendulum? c. The man saves himself by smearing food on his ropes so that rats chew through them. He does so when he has no more than 12 cycles before the pendulum will make contact with him. How much time does it take the rats to chew through the ropes? FIGURE P16.39
You are part of a scientific expedition that landed in the planet Martech. The planet has an atmosphere of an unknown gas. In your preparation for the mission you prepared the following table, a resonance tube and a sonic device that can produce three frequencies: 261Hz, 330Hz and 512Hz. You measured the temperature of the gas in the atmosphere and recorded 20 degree Celsius. you need to determine the gas of the atmosphere on the planet Martech. The lengths of the resonance tube were: 0.202m, 0.13m, and 0.256m a) Which length of the resonance tube correspond to the frequency of the sonic device? F1=261 Hz; L1= F2=330 Hz; L2= ;F3=512 Hz; L3= Calculate the speed of sound for the three different frequencies.
HW1//: find the amplitude, period, and frequency for the following waveform. a. 20 sin 377t b. 5 sin 7541 c. 10° sin 10,000t e. -7.6 sin 43.6t d. 0.001 sin 942t f. ) sin 6.2831 HW/2 Find the phase relationship between the waveforms of cach set: a. v= 4 sin(wr + 50°) i = 6 sin(wr + 40°) b. v = 25 sin(ot - 80°) i = 5 x 10- sin(wr - 10°) c. v= 0.2 sin(wt - 60°) i = 0.1 sin(wr + 20°) d. v = 200 sin(wt i = 25 sin(wr 210°) 60°) HW/3 Repeat Problem 29 for the following sets: a. v = 2 cos(ot - 30°) i - 5 sin(wt + 60°) c. v= -4 cos(wt + 90°) i = -2 sin(wt + 10°) b. v = -1 sin(wt + 20°) i - 10 sin(wr - 70°)
What a sound wave has a frequency of 727 HZ an air and a way blank of 0.51 M. what is the temperature of the air? relate the speed of sound in air to temperature in unit of kelvin but answer in units of celsius assume the velocity of sound at 0ﾟC Is 325M/S answer in units of deg C
A brown bat uses echolocation to find mosquitos and eat on a hot 27.8°C summer night. 1. The bat sends out an ultrasonic pulse of sound and hears an echo from a mosquito after 2.37 × 10¬ª S. How far away is the mosquito? 2. Estimate the size of a mosquito. 3. In order to detect prey, bats must use a wavelength that is the same size, or smaller than the size of their prey. Estimate the minimum frequency a bat needs to use to detect mosquitos.
Consider a sound wave in air that has displacement amplitude 2.40X10-² mm. For related problemsolving tips and strategies, you may want to view a Video Tutor Solution of Amplitude of a sound wave in air. Part A Calculate the pressure amplitude for frequencies of 158 Hz . Take the bulk modulus of the air to be 1.42 × 105 Pa and the speed of sound to be 344 m/s Express your answer in pascals. pmaz = |98.30 Part B Submit Previous Answers Request Answer Be x Incorrect; Try Again; 4 attempts remaining pmaz = |983 Calculate the pressure amplitude for frequencies of 1580 Hz. Take the bulk modulus of the air to be 1.42 × 105 Pa and the speed of sound to be 344 m/s. Express your answer in pascals. Part C ? Be pmax = |9830 Pa Submit Previous Answers Request Answer (3 ? x Incorrect; Try Again; 5 attempts remaining Re 6 Calculate the pressure amplitude for frequencies of 1.58x104 Hz . Take the bulk modulus of the air to be 1.42 × 105 Pa Express your answer in pascals. Pa #3 ? Pa Submit Previous…
Consider a solid with linear lattice in which the interatomic distance is equal to 4.0A°. Calculate the velocity of sound in the solid by considering the cutoff frequency equal to 3.0 THz. Answer Choices: a. 2400 m/s b. 3600 m/s c. 1200 m/s d. 4800 m/s
The image shows a Wave Energy Converter (WEC), where the buoyant top floats near the water's surface and is attached to a heavy base resting on the seabed. seabed base Which statement correctly describes how the WEC moves to generate electricity from the amplitude of ocean waves? O The buoyant top slows down the moving water waves. O The buoyant top changes the direction of the water waves. O The buoyant top moves back and forth with the water waves. O The buoyant top moves up and down with the water waves. hp DII %23 2$ & 4. 5 6 8. q e t y tab j hift C alt alt
A girl is playing a trumpet. The sound waves produced are traveling through air to your ear. Which one of the following statements is false concerning this situation? O The sound travels at the speed of light to your ear. O The loudness of the sound wave involves the size of the oscillations in air pressure. O A high-frequency sound that the trumpet produces is interpreted as a high-pitched sound. O Air molecules between the trumpet and your ear vibrate back and forth parallel to the direction the waves are traveling. O The sounds from the trumpet are longitudinal waves.
7 1. A person holds a rifle horizontally and fires at a target. The bullet has a muzzle speed of 190 m/s, and the person hears the bullet strike the target 1.10 s after firing it. The air temperature is 69°F. What is the distance to the target? m 2 W S X H command eboute and boare the ocho collected from a cliff wall 2.90 later. If the air temperatura lc 2006 bow far is the # 3 E D C $ 4 R F O Search or type URL % 5 V. T G MacBook Pro 6 B Y H & 7 U N . 8 J I M ( .0 9 K O V. I дв Mi > C O L P 11332 command V : ; t { C option
D A- Find the free path rate of phonons à in germanium at a temperature of 300 kelvin, since you know that the coefficient of thermal conductivity is equal to 80 W m¹ k¹, the temperature of Debye is 360 kelvin, and the rate of sound speed in germanium is 4800 m/s Buana the