Answered: A pipe open at both ends has a… | bartleby

Related questions

Question

A pipe open at both ends has a fundamental frequency of 145 Hz. A second pipe, which is closed at one end, vibrates at this frequency in its fourth harmonic mode. What is the length of the pipe a. open at both ends and b. closed at one end?

Expert Solution

Step by step

Solved in 4 steps

SEE SOLUTION Check out a sample Q&A here

Blurred answer

Similar questions

A stretched string and an air column which is open at both ends are in resonance with each other. The air column is 55 cm. long, filled with air at room temperature (speed is 340 m/s), and is vibrating at its 3rd harmonic frequency. The string is 60 cm. long and has a total mass of 5 grams. If the string is vibrating in it's 4th harmonic frequency (and this matches the pipe’s third harmonic) a) what is the fundamental frequency of the vibrating air column in the pipe? b) what is the speed of the wave in the string? c) what is the tension in the string?
A string experiences several harmonic frequencies. Two successive frequencies are 325Hz and 390Hz. a) What is the fundamental frequency? b) What is the next harmonic higher than 195Hz? c) Which harmonic is this?
A string of length 2 m with both ends fixed is plucked by several curious Physics 9B students. They observe that the standing wave with six nodes between the two fixed ends has a frequency 150 Hz higher than the standing wave with fournodes between the two fixed ends.a) Which harmonic is the standing wave with four nodes between the ends? How about the standing wave with six nodes between the ends?b) What is the frequency of the first harmonic?c) What is the frequency of the standing wave with four nodes between the ends?d) What is the speed at which waves travel on the string?e) Suppose this string is part of a musical instrument. When the string vibrates at its fundamental frequency, what is the wavelength of the sound waves produced? You may use v = 343 m/s for the speed of sound in air.f) Repeat parts a)-c) for the case that one end of the string is fixed but the other end is free.
a. A wooden flute, open at both ends, is 0.5 m long. Determine its fundamental vibration frequency assuming the speed of sound in air is 340 m/s b. How far from one end should a finger hole be placed to produce a sound whose frequency is 44 times that calculated in the first part.
A string of mass 9 grams is stretched to a length of 0.4 meters and fastened at both end so that it can freely vibrate. The tension on the string is 2000 Newtons. What is the linear density of the string? kg/m Submit Answer Tries 0/2 At what speed would a wave propagate on this string? m/s Submit Answer Tries 0/2 What is the wavelength of the first harmonic (also called the fundamental frequency) of standing wave created by the vibrating string? Submit Answer Tries 0/2 What is the fundamental frequency of the vibrating string? Hz
Pipe A is 2 m long and open at both ends. Pipe B is open at one end and closed at the other. Determine the length of pipe B so that it has the same fundamental frequency as A.
A steel piano wire is 82.0 cm long and has a mass of 2.80 g. If the tension of the wire is 590 N, what is the sixth harmonic frequency?
The ear canal can be thought of as a tube leading from the outer ear to the ear drum that is closed at one end. The typical length of an adult human ear canal is 2.5 cm. What is the fundamental resonant frequency of the ear canal? Assume the air inside it is at body temperature (37°C).