Sound Sound is a longitudinal wave that travels through a medium. The speed of sound depends on the properties of the medium. It travels faster in a.

Slides:

Advertisements

Similar presentations

Chapter 12 Sound. What is sound? Sound is a compressional wave which travels through the air through a series of compressions and rarefactions.

Advertisements

Physics 12 Source: Giancoli Chapters 11 and 12

Chapter 12 SOUND.

SOUND WAVES Sound is a longitudinal wave produced by a vibration that travels away from the source through solids, liquids, or gases, but not through a.

Chapter 14 Sound.

Sound Chapter 15.

Phys 250 Ch15 p1 Chapter 15: Waves and Sound Example: pulse on a string speed of pulse = wave speed = v depends upon tension T and inertia (mass per length.

All sounds are produced by the vibration of matter. If there is no vibration, there is no sound.

Chapter 14 Sound AP Physics B Lecture Notes.

Summary Sinusoidal wave on a string Wavefunction.

Chapter 17 Sound Waves. Introduction to Sound Waves Waves can move through three-dimensional bulk media. Sound waves are longitudinal waves. They travel.

PHYS16 – Lecture 35 Sound December 3, 2010 “Since light travels faster than sound, is that why some people appear bright until you hear them speak?”

Cutnell/Johnson Physics 8th edition Reading Quiz Questions

Lecture 1 – Waves & Sound c) Sound.

Doppler Effect Physics 202 Professor Lee Carkner Lecture 11.

Halliday/Resnick/Walker Fundamentals of Physics 8th edition

SOUND WAVE PROPERTIES Sound longitudinal Sound is a longitudinal (Mechanical)wave caused by a vibrating object Molecules collide, producing sound Examples:

University Physics: Waves and Electricity Ch17. Longitudinal Waves Lecture 5 Dr.-Ing. Erwin Sitompul

Sound Review. What type of wave is a sound wave? 1.Mechanical and Transverse 2.Mechanical and Longitudinal 3.Electromagnetic and Transverse 4.Electromagnetic.

Chapter 3: Sound Wave Intensity of Periodic Sound Waves

SOUND A vibrating object, such as your voice box, stereo speakers, guitar strings, etc., creates longitudinal waves in the medium around it. When these.

Waves and Sound Ch

Chapter Review. Ch. 11 page , 4, 7, 8, 12, 14, 16, 19, 21, 23-25, 31, 32, 35, 37, 41, Oscillation about an equilibrium position in.

Chapter 10: Sound Section 1: The Nature of Sound

Chapter 13 - Sound 13.1 Sound Waves.

2 pt 3 pt 4 pt 5pt 1 pt 2 pt 3 pt 4 pt 5 pt 1 pt 2pt 3 pt 4pt 5 pt 1pt 2pt 3 pt 4 pt 5 pt 1 pt 2 pt 3 pt 4pt 5 pt 1pt Audio File I heard thatAmped up A.

Sound Overview The Facts of Sound The Ear and Sound Sound Vocabulary Musical Instruments and Sound.

Unit 10: Sound.

The wavelength, λ, is 20 m. What is the speed of this wave? CT Time (sec) A) 1 m/s B) 6 m/s C) 10 m/s D) 15 m/s E) None of the above/not enough.

Chapter 14 Waves and Sound

Chapter 15 Sounds.

Chapter 17 Sound Waves: part two HW 2 (problems): 17.22, 17.35, 17.48, 17.58, 17.64, 34.4, 34.7, Due Friday, Sept. 11.

A longitudinal wave is: 1.A wave where the particle oscillation is perpendicular to the direction of wave motion 2.A wave where the particle oscillation.

Types of Traveling Waves

Sound Physics. Sound Source All sounds are produced by the vibrations of material objects The frequency of sounds is often described by the word pitch.

A longitudinal wave is: 1.A wave where the particle oscillation is perpendicular to the direction of wave motion 2.A wave where the particle oscillation.

Physics I Honors 1 Waves and Sound Intensity Doppler Effect.

© Houghton Mifflin Harcourt Publishing Company Preview Objectives The Production of Sound Waves Frequency of Sound Waves The Doppler Effect Chapter 12.

Sound Bites. Basics Sound is a mechanical, longitudinal wave. The medium usually associated with sound is air, but sound can travel through both liquids.

Waves Harmonic Motion, Wave Types, Wave Speed, Interference.

Physics 101: Lecture 33 Sound

Chapter 15 - Sound Sound wave is a longitudinal wave.

1 Wave Interference: Beats 2 Beats Previously we considered two interfering waves with the same . Now consider two different frequencies. When waves.

Chapter 12 Sound Producing a Sound Wave Characteristics of Sound Waves The Speed of Sound Spherical and Plane Waves The.

L 23 – Vibrations and Waves [3]  resonance   clocks – pendulum   springs   harmonic motion   mechanical waves   sound waves  golden rule for.

Ms. Barlow’s 8th Grade Physical Science Class

Introducing Sound Waves David William D. Ecoben III-Archimedes.

Chapter 12 Preview Objectives The Production of Sound Waves

Sound Waves March 22-23, The nature of sound What is a tuning fork? How are they used? How do we know that sound is a wave? Visualizing sound waves.

Physics Mrs. Dimler SOUND.  Every sound wave begins with a vibrating object, such as the vibrating prong of a tuning fork. Tuning fork and air molecules.

Sound Waves  Sound is a longitudinal wave, meaning that the motion of particles is along the direction of propagation.  sound waves are divided into.

Today (Finish Chapter 13, Sound)  Temperature and Heat Concepts Tomorrow (Start Chapter 14)  Standing Waves  Beats  Doppler Effect  Example Problems.

Characteristics of Waves Chapter 15.2 Notes. Wave Properties There are several wave properties, such as amplitude, wavelength, period, and frequency Amplitude.

Sound, Waves, uh yea.. Sound! Come  Pitch, loudness, and timbre are all perceived attributes of sound.  Pitch is the perceived frequency.

Chapter Summary 15.1 Properties and Detection of Sound

Waves and Sound Clickers

youtube vibrating string

Sound Longitudinal wave requires a medium (cannot travel in a vacuum)

Notes 21.1 – Properties of Sound

A longitudinal wave is:

1. Which of the following is a false statement?

All sounds are produced by the vibration of matter

Sound Waves, Pitch, and Loudness

Sound, Decibels, Doppler Effect

Summary Sinusoidal wave on a string. Summary Sinusoidal wave on a string.

Presentation transcript:

Sound Sound is a longitudinal wave that travels through a medium. The speed of sound depends on the properties of the medium. It travels faster in a solid than in a liquid, and it travels faster in a liquid than a gas. Air: 330 m/sWater: 1500 m/s Aluminum: 6400 m/sWood: 4000 m/s

Poll You tap the edge of the pool. Friend A is under water 10 m from where you tapped. Friend B is out of the water 10 m from where you tapped. Who will hear the sound first? 1.Friend A 2.Friend B 3.Neither, because they will hear the sound at the same time.

Sinusoidal sound wave A continuous, single-frequency tone is described by a sinusoidal wave. It can be produced by a speaker that oscillates in simple harmonic motion.

Superposition Most periodic sound waves are a superposition of sine waves. Superposition means to add sine waves. Examples: voice recognition, BOSE noise- canceling headphones

Beats Beats occur when two sine waves of different frequencies are added together. The amplitude of the sum of the waves varies between zero and a maximum value with a frequency called the beat frequency.

t y1y1 t y2y2 1.0 s Two subsonic (below frequencies audible to humans) signals are shown here over a one second time interval. A creature that can hear at these frequencies hears a beat frequency of _______ Hz. A. 1 B. 2 C. 12 D. 24 E. 25

Poll A person is tuning his guitar. The low E string is tuned to 156 Hz. When playing the same note on another string, he hears a beat frequency of 2 Hz. What is the frequency of the other string? Hz Hz 3.It could be either 154 Hz or 158 Hz. 4.None of the above.

Poll Suppose that the guitarist in the previous question decides to increase the tension on the string he is tuning (in order to get it in tune). He hears the beat frequency increase as he increases the tension. What should he do? 1.Continue to increase the tension until the strings are in tune. 2.Turn the key the other way and instead decrease the tension until the strings are in tune. 3.Give up and hire someone else to tune the guitar.

Sound level (loudness) Sound level is related to intensity. Intensity is proportional to amplitude squared. The units of sound level are decibels. where

Example To increase the sound level by 20 dB, by what factor must you increase the sound intensity?

Typical sound levels

Example What is the intensity of sound with a measured sound level of 100 dB?

Poll The sound level of a motorcycle is about 100 dB. The sound level of normal conversation is about 70 dB. How much more intense is the sound from a motorcycle than the sound from a person’s voice during conversation? 1.30 times more intense times more intense times more intense 4.3 times more intense times more intense

Doppler Effect The frequency of sound heard by the detector is different than the frequency of sound emitted by the source, depending on the relative motion of the source and detector.

Doppler shift The upper sign in each case corresponds to the detector and source moving away from each other. The lower sign in each case corresponds to the detector and source moving toward each other.

The speaker below is mounted on wheels. When it is being pulled in the direction shown at constant speed, the frequency that the ear hears will be be ____________ when the speaker is stationary. v A. lower than B. the same as C. higher than

NYPD An ambulance and a police rescue vehicle are traveling in the same direction toward the scene of an accident. The ambulance has its siren on. When the ambulance is going faster than the rescue vehicle, the siren frequency heard by the police officers in the rescue unit will be _________________ when both vehicles are stationary A. higher than B. the same as C. lower than

NYPD An ambulance and a police rescue vehicle are traveling in the same direction toward the scene of an accident. The ambulance has its siren on. When the rescue vehicle is gaining on the ambulance, the siren frequency heard by the police officers in the rescue unit will be _________________ when both vehicles are stationary A. higher than B. the same as C. lower than

Example Sound of frequency 1000 Hz is coming toward you with a velocity of 20 m/s. You are at rest. The speed of sound in air is about 330 m/s. What frequency will you hear?

Doppler Shift for Light Light from a star moving away from us is shifted to lower frequency (longer wavelength) which is toward the red end of the visible spectrum -- red shifted. Light from a star moving toward us is shifted to higher frequency (shorter wavelength) which is toward the blue end of the visible spectrum -- blue shifted. We use Doppler shifts to measure (radial) speeds of stars.