Part 2)An organ pipe of length L = 4.6 m is open at both ends. It is driven to oscillate with a standing wave that has two nodes within the pipe.(a) What is the wavelength of the standing wave?m(b) If the speed of sound in air is 330m/s, what is the frequency that the organ pipe is oscillating at in this mode?Hz (a) A simple pendulum of length e = 2.50 m and mass m = 16.6 kg is swinging in simple harmonic motion. Calculate the period of thisocillation.T =(b) The pendulum is stopped and the massless string of the pendulum is replaced with a spring of the same length. The mass is setoscillating on this spring and that oscillation is observed to have a frequency of f = 0.747 Hz. What is the spring constant of the spring?k =N/m

Answered: Image /qna-images/answer/c84da261-38cf-4720-be8d-503b157b0d89.jpg

Part 2) An organ pipe of length L = 4.6 m is open at both ends. It is driven to oscillate with a standing wave that has two nodes within the pipe. (a) What is the wavelength of the standing wave? (b) If the speed of sound in air is 330m/s, what is the frequency that the organ pipe is oscillating at in this mode? Hz

Part 2) An organ pipe of length L = 4.6 m is open at both ends. It is driven to oscillate with a standing wave that has two nodes within the pipe. (a) What is the wavelength of the standing wave? (b) If the speed of sound in air is 330m/s, what is the frequency that the organ pipe is oscillating at in this mode? Hz

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

See similar textbooks

Related questions

Q: À speaker produces 100 (w) of power, If the speaker projects sound uniformly into the forward…

Q: Two trains on separate tracks move toward each other. Train 1 has a speed of 113 km/h; train 2, a…

Q: A source of sound waves of frequency 1.00 kHz is traveling through the air at 0.270 times the speed…

A: Given A source of sound waves of frequency 1.00 kHz is traveling through the air at 0.270 times the…

Q: Organ pipe A, with both ends open, has a fundamental frequency of 310 Hz. The third harmonic of…

A: Given: The frequency is given as 310 Hz Assume the sound's speed is 343 m/s

Q: 3) A herd of 7 screeching elephants makes a sound of 117 dB. a) What is the intensity produced by…

A: Number of elephants screeching, The intensity of sound in decibels,

Q: Two trains on separate tracks move toward each other. Train 1 has a speed of 129 km/h; train 2, a…

A: Given, speed of the train 1 (observer), vo = 129 kmh speed of train 2 (source), vs = 89.0 kmh…

Q: 2. A 1.5−m-long string fixed at both ends vibrates at resonant frequencies of 930 Hz and 1395 Hz,…

A: Given value--- Length = 1.5 m. both ends vibrates at resonant frequencies of 930 Hz and 1395 Hz.…

Q: Two waves are described by the following equations. 4 ₁ = (3 m)sin X- m 2 = (3 m)sin X- 4 m 3.0 m…

A: given y1=(3m)sin(4mx-700st)y2=(3m)sin(4mx-700st-2) When the two waves are added…

Q: Organ pipe A, with both ends open, has a fundamental frequency of 300 Hz. The third harmonic of…

Q: An ultrasound machine can measure blood flow speeds. Assume the machine emits acoustic energy at a…

A: original frequency (f) = 2.2×106 Hz speed of wave in human tissue (v) = 1580 m/s speed of blood (v')…

Q: In an acoustics lab you have a 60 m long pipe that contains very cold air, in fact T = – 46 °C.…

A: Length of pipe L = 60 m Temperature T = -46° C Wavelength of sound wave λ = 1.5 m Time taken to…

Q: The end of a string is being oscillated in SHM sending a transverse wave down the string which is…

A: At , x=0.4 m & t=5 s y = 1.2cm . Sin [2pi(5/0.01 - 0.4/0.3)] y = 1.2cm × (-0.949) y = -1.04 cm

Q: A transverse wave traveling on a Slinky that is stretched to a total length of 3.5 m takes 4.5 s to…

Q: 1) A transverse sinusoidal wave is generated at one end of a long, horizontal string by an ocillator…

A: Solution given below:

Q: As you stand ncar a railroad track, a train passes by at a speed of 31.1 m/s while sounding its horn…

A: The problem is based upon the Doppler effect. Doppler Effect refers to the change in wave frequency…

Q: A doctor using 3 MHz ultrasound measures a 6500 Hz frequency shift as the ultrasound reflects from…

Q: The displacement of the air molecules in a sound wave is modeled with the wave function s(x, t) =…

Q: Organ pipe A, with both ends open, has a fundamental frequency of 260 Hz. The third harmonic of…

Q: A guitar player tunes the fundamental frequency of a guitar string to 390 Hz. (a) What will be the…

Q: 5.20 m from one speaker and 3.80 m from the other. What is the third lowest frequency at which…

Q: Organ pipes, open at one end, resonate best at their first resonant length. Two pipes have length…

A: The two pipes have lengths of 23 cm and 30 cmBoth the pipes are open at one end and closed at the…

Q: 1) The equation below describes the variation of pressure at different positions and times (relative…

A: The given equation is a mathematical representation of a sound wave. It describes how the pressure…

Q: Two waves are traveling in the same direction along a stretched string. The waves are 90.0° out of…

A: Lets name the amplitude of the waves be R1 and R2 Waves are 90 out of phase Amplitude each wave is…

Q: An organ pipe has a length of 2.45 m and is open at both ends. Determine the fundamental frequency…

A: It is given that,

Q: The pipes of a pipe organ function as open pipes (open at both ends). A certain pipe must produce a…

A: Determine the speed of sound at a temperature of 150C.

Q: A 38.0-Hz sound wave is barely audible at a sound intensity level of 60.0 dB. The density of air at…

A: The frequency of the sound wave is f=38.0 Hz The sound intensity level is L=60 dB The density of air…

Concept explainers

Properties of sound

A sound wave is a mechanical wave (or mechanical vibration) that transit through media such as gas (air), liquid (water), and solid (wood).

Quality Of Sound

A sound or a sound wave is defined as the energy produced due to the vibrations of particles in a medium. When any medium produces a disturbance or vibrations, it causes a movement in the air particles which produces sound waves. Molecules in the air vibrate about a certain average position and create compressions and rarefactions. This is called pitch which is defined as the frequency of sound. The frequency is defined as the number of oscillations in pressure per second.

Categories of Sound Wave

People perceive sound in different ways, like a medico student takes sound as vibration produced by objects reaching the human eardrum. A physicist perceives sound as vibration produced by an object, which produces disturbances in nearby air molecules that travel further. Both of them describe it as vibration generated by an object, the difference is one talks about how it is received and other deals with how it travels and propagates across various mediums.

Question

Part 2)
An organ pipe of length L = 4.6 m is open at both ends. It is driven to oscillate with a standing wave that has two nodes within the pipe.
(a) What is the wavelength of the standing wave?
m
(b) If the speed of sound in air is 330m/s, what is the frequency that the organ pipe is oscillating at in this mode?
Hz

(a) A simple pendulum of length e = 2.50 m and mass m = 16.6 kg is swinging in simple harmonic motion. Calculate the period of this
ocillation.
T =
(b) The pendulum is stopped and the massless string of the pendulum is replaced with a spring of the same length. The mass is set
oscillating on this spring and that oscillation is observed to have a frequency of f = 0.747 Hz. What is the spring constant of the spring?
k =
N/m

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

This is a popular solution!

SEE SOLUTION Check out a sample Q&A here

Step 1 : Given Values

VIEW

Step 2 : Concepts and Calculations

VIEW

Trending now

This is a popular solution!

Step by step

Solved in 2 steps with 2 images

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.

Similar questions

Two waves produce the following displacements on the same string:y1 = 24.0 mm sin(-1.25πx + 9πt)y2 = 35.0 mm sin(0.40πx + 2.88πt)where x is in meters, y is in millimeters and t is in seconds. At t = 4.00 s, fin the resulting displacement at:a) X = 2.16 m
4) You have a pipe that is closed at one end. In a 22.0 °C room, you find that two of the harmonics occur at 294 Hz and 490 Hz. a) What is the shortest possible length of this pipe? b) What would the fundamental frequency be if you opened the other end of the pipe?
You are blowing into a hollow tube whose opposite end is covered by your hand. You hear the sound of the resulting standing wave as you blow into this tube. What happens to the frequency of the sound coming from the tube when you remove your hand? Decrease Increase Unchanged
Displacements of two waves on a string:y1 = 24.0 mm sin(-1.25πx + 9πt)y2 = 35.0 mm sin(0.40πx + 2.88πt)where x is in meters, y is in millimeters and t is in seconds. At t = 4.00 s, Calculate the resulting displacement at:a) X = 2.16 mb) X = 2.56 m
An alarm clock is ringing inside a jar. You are able to pump air out with a vacuum pump. What happens as more and more air is removed? a) The intensity of the sound from the bell does not change. b) The speed of the sound from the bell gradually increases. O c) The frequency of the sound from the bell gradually increases. d) The sound intensity from the bell gradually decreases. e) The frequency of the sound from the bell gradually decreases.
3.7 Two sinusoidal waves in a string are defined by the wave functions Y₁ = 2.20 sin (17.0x - 35.0t) Y₂ = 2.20 sin (29.0x - 45.0t) where x, y₁, and y₂ are in centimeters and it is in seconds. (a) What is the phase difference between these two waves at the point x = 5.00 cm at t = 2.00 s? (Your answer should be between 0° and 360°.) (b) What is the positive x value closest to the origin for which the two phases differ by ± at t = 2.00 s? (At that location, the two waves add to zero.) cm
PLEASE HELP!!!
WT-2 A pipe closed at one end and open at the other has a length of 0.750m. Jiatai places a speaker producing a low sound frequency above the open end of the tube. He then increases the frequency slowly. The pipe is in air at sea level. a) Draw the possible standing wave patterns for the sound waves in the tube starting with the lowest frequency. lowest frequency fa fo fa highest open end L=0.750m closed end L%3D L= L= b) Below each pattern write the tube-length-to-wavelength relationship for each pattern. c) Write the general symbolic relationship for the frequency of the n" harmonic, fn. Specify the possible values for n. d) Put the known information into your equation and find the numerical value of the frequencies fa, f, fe, and få. e) Jiatai can hear frequencies up to 19,980HZ. What is the highest frequency of the highest harmonic that Jiatai can hear from this tube and what is the harmonic number n of that harmonic? Answers WT-1 a) L=/4, L=32J4, L=52/4, L=7/4 b) 0.166m WT-2 a)---…
In an acoustics lab you have a 120 m long pipe containing very cold air. Suppose that using a speaker you cause a sinusoidal wave of sound with frequency 150 Hz and wavelength 1.9 m to travel down the pipe. i)How long does it take for your sinusoidal wave to travel from one end of the pipe to the other end of the pipe? ii)What is the temperature of the air in the pipe?
Two strings, each 15.3 m long, are stretched side-by-side. One string has a mass of 78.0 g and a tension of 220.0 N. The second string has a mass of 58.0 g and a tension of 194.0 N. A pulse is generated at one end of each string simultaneously. A) What is the speed of the wave on the first string? in m/s B) What is the speed of the wave on the second string? in m/s C) Once the faster pulse reaches the far end of its string, after what additional time interval will the slower pulse reach the end of its string? in ms
In an acoustics lab you have a 60 m long pipe that contains very cold air, in fact T = – 46 °C. Suppose that using a speaker you cause a sinusoidal wave of sound with wavelength 1.5 m to travel down the pipe, going from one end of the pipe to the other. ii) What is the frequency of the sound in the pipe? a) 1.5×102 Hz b) 2.0×102 Hz c) 2.5×102 Hz d) 3.0×102 Hz e) 3.5×102 Hz
Two adjacent natural frequencies of an organ pipe are determined to be 870 Hz and 986 Hz. (Assume the speed of sound is 343 m/s.) (a) Calculate the fundamental frequency of this pipe. Hz (b) Calculate the length of this pipe. m