Assume the speed of sound in air is 340 m/s. Determine the first three standing wave...

A pipe is 2.37 m long. (a) Determine the frequencies of the first three harmonics if...

A pipe is 2.37 m long. (a) Determine the frequencies of the first three harmonics if the pipe is open at both ends. Take 344 m/s as the speed of sound in air. f1 = 72.6 Correct: Your answer is correct. Hz f2 = 145.2 Correct: Your answer is correct. Hz f3 = 217.8 Correct: Your answer is correct. Hz (b) How many harmonic frequencies of this pipe lie in the audible range, from 20 Hz to 20000 Hz? 275...

Sound in Pipe Standing Wave A mode 4 standing wave has set up in a 60...

Sound in Pipe Standing Wave A mode 4 standing wave has set up in a 60 cm pipe that is open at both ends. The gas in and surrounding the pipe is air with sound velocity of 343 m/s. Determine the frequency of the standing wave in the pipe. The air in and surrounding the pipe is replaced by an unknown gas that results in a standing wave of the same frequency but with mode = 6. Determine the sound...

An organ pipe is 127 cmcm long. The speed of sound in air is 343 m/sm/s....

An organ pipe is 127 cmcm long. The speed of sound in air is 343 m/sm/s. A. What are the fundamental and first three audible overtones if the pipe is closed at one end? B. What are the fundamental and first three audible overtones if the pipe is open at both ends?

An organ pipe is 130 cm long. The speed of sound in air is 343 m/s....

An organ pipe is 130 cm long. The speed of sound in air is 343 m/s. Part A What are the fundamental and first three audible overtones if the pipe is closed at one end? Express your answers using three significant figures separated by commas. Part B What are the fundamental and first three audible overtones if the pipe is open at both ends? Express your answers using three significant figures separated by commas.

part 1. A 9.00-m long string sustains a three-loop standing wave pattern as shown. The string...

part 1. A 9.00-m long string sustains a three-loop standing wave pattern as shown. The string has a mass of 45 g and under a tension of 50 N. a. What is the frequency of vibration? b. At the same frequency, you wish to see four loops, what tension you need to use. Part 2. a. Determine the shortest length of pipe, open at both ends, which will resonate at 256 Hz (so the first harmonics is 256Hz). The speed...

The average speed of sound in air is approximately 340 m/s. Is this true? If yes,...

The average speed of sound in air is approximately 340 m/s. Is this true? If yes, what does a speed of 680 m/s in an air column represent or how should it be interpreted considering the average is 340 m/s?

A musician in a car travelling at a speed of 28.0 m/s plays a horn (modeled...

A musician in a car travelling at a speed of 28.0 m/s plays a horn (modeled as an open-closed tube 33.0 cm long). The note played is at its fundamental frequency. What frequency does an observer standing on the side of the road hear as the car approaches her? Assume the speed of sound is 340 m/s.

What are the wavelengths and frequencies of the first three resonance possibilities for air (assume v...

What are the wavelengths and frequencies of the first three resonance possibilities for air (assume v = 340 m/s) in a 2.00 m long open tube? Please draw the three possibilities in diagrams, thanks!

An organ pipe is 5.90 m long and is closed at one end. (The speed of...

An organ pipe is 5.90 m long and is closed at one end. (The speed of sound at T = 20.0°C is v = 343 m/s.) What is the second lowest standing wave frequency for the organ pipe? What is the third lowest standing wave frequency for the organ pipe? What is the fourth lowest standing wave frequency for the organ pipe? The sound level 23.2 m from a loudspeaker is 63.4 dB. What is the rate at which sound...

A stove is connected to a stove pipe of length L=3m. When the wind blows, the...

A stove is connected to a stove pipe of length L=3m. When the wind blows, the pipe sometimes “sings” (just like blowing across the top of a coke bottle). The fundamental frequency and lowest few overtones are usually heard. Assume the speed of sound to be 340 m/s. a) Assume that the pipe is “open” on one end and “closed” on the other. Draw a displacement standing wave diagram for this case and determine the fundamental frequency of sound that...