Sound waves... light waves... water waves...

Similar documents
Physics Mechanics

Waves & Interference

Mechanical waves Electromagnetic waves

Chapter 14: Waves. What s disturbing you?

Chs. 16 and 17 Mechanical Waves

Preview. Vibrations and Waves Section 1. Section 1 Simple Harmonic Motion. Section 2 Measuring Simple Harmonic Motion. Section 3 Properties of Waves

Slide 2 / 28 Wave Motion. A wave travels along its medium, but the individual particles just move up and down.

Lab 2: Superposition of waves on a string

Pre AP Physics: Unit 7 Vibrations, Waves, and Sound. Clear Creek High School

Superposition of waves on a string

Vibrations are the sources of waves. A vibration creates a disturbance in a given medium, that disturbance travels away from the source, carrying

Slide 1 / The distance traveled by a wave in one period is called? Frequency Period Speed of wave Wavelength Amplitude

Mechanical Waves. Chapter 15. PowerPoint Lectures for University Physics, Thirteenth Edition Hugh D. Young and Roger A. Freedman

Question. A. Incorrect! Check the definition for period. B. Incorrect! Check the definition for speed.


Chapter 14 Waves. Apr 30 7:11 AM

Waves and Sound. Honors Physics

Waves Multiple Choice

Doppler Effect. PHY132H1F Introduction to Physics II Class 3 Outline:

Chapter 11 Waves. Waves transport energy without transporting matter. The intensity is the average power per unit area. It is measured in W/m 2.

Chapter 15 Wave Motion. Copyright 2009 Pearson Education, Inc.

Algebra Based Physics

Units of Chapter 14. Types of Waves Waves on a String Harmonic Wave Functions Sound Waves Standing Waves Sound Intensity The Doppler Effect

Today: waves. Exam Results. Wave Motion. What is moving? Motion of a piece of the rope. Energy transport

Waves-Wave Basics. 1. Which type of wave requires a material medium through which to travel? 1. sound 2. television 3. radio 4.

15815 Super Spring - Student

PHYSICS - GIANCOLI CALC 4E CH 15: WAVE MOTION.

Define transverse waves and longitudinal waves. Draw a simple diagram of each

Chapter 11 Waves. Waves transport energy without transporting matter. The intensity is the average power per unit area. It is measured in W/m 2.

Wave Motion. interference destructive interferecne constructive interference in phase. out of phase standing wave antinodes resonant frequencies

Waves Practice Problems AP Physics In a wave, the distance traveled by a wave during one period is called:

Chapter 14. Vibrations and Waves

Phys1111K: Superposition of waves on a string Name:

Lecture Outline Chapter 14. Physics, 4 th Edition James S. Walker. Copyright 2010 Pearson Education, Inc.

Sinusoidal Waves. Sinusoidal Waves. Sinusoidal Waves

is shown in Fig. 5.1.

Chapter 16. Waves-I Types of Waves

i-clicker Discussion Question

LAB 10 Waves and Resonance

Waves. harmonic wave wave equation one dimensional wave equation principle of wave fronts plane waves law of reflection

6. An oscillator makes four vibrations in one second. What is its period and frequency?

Chapter 12: Mechanical Waves and Sound

Exam Results, HW4 reminder. Wave Motion. Today: waves. What is moving? Motion of a piece of the rope. Exam Results. Average

i-clicker Discussion Question

Similarly to elastic waves, sound and other propagated waves are graphically shown by the graph:

Lab 12 Standing Waves

Chapter # 08 Waves. [WAVES] Chapter # 08

Core Concept. PowerPoint Lectures Physical Science, 8e. Chapter 5 Wave Motions and Sound. New Symbols for this Chapter 2/20/2011

Questions. Background. Equipment. Activities LAB 3. WAVES

Chapter 19: Vibrations And Waves

Harmonics and Sound Exam Review

20.1 Waves. A wave is an oscillation that travels from one place to another. Because waves can change motion, they are a travelling form on energy.

PHYS 102 Quiz Problems Chapter 16 : Waves I Dr. M. F. Al-Kuhaili

Conceptual Physics. Chapter 25: Vibrations and Waves Mr. Miller

Chapter 19: Vibrations and Waves

Lab 12 Standing Waves

Waves. Mechanical Waves A disturbance in matter that carries energy from one place to another.

Waves Chapter Problems

Topic 4.4 Wave Characteristics (2 hours)

Main Ideas in Class Today

Waves-Wave Basics. 1. Which type of wave requires a material medium through which to travel? 1. sound 2. television 3. radio 4.

Traveling Waves vs. Standing Waves

SPH3U Sec.9.2.notebook. November 30, Free End Reflections. Section 9.2 Waves at Media Boundaries

23.1 Period and Frequency

Chapters 25: Waves. f = 1 T. v =!f. Text: Chapter 25 Think and Explain: 1-10 Think and Solve: 1-4

CHAPTER 8: MECHANICAL WAVES TRANSMIT ENERGY IN A VARIETY OF WAYS

Ch13. Vibrations and Waves HW# 1, 5, 9, 13, 19, 29, 35, 37, 39, 41, 43, 47, 51, 53, 61

g L Agenda Chapter 13 Problem 28 Equations of Motion for SHM: What if we have friction or drag? Driven Oscillations; Resonance 4/30/14 k m f = 1 2π

Lecture 8. Sound Waves Superposition and Standing Waves

a wave is a rhythmic disturbance that carries/transfers energy through matter or space A repeating movement

MECHANICAL WAVES AND SOUND

Section 1: Types of Waves

Introduction to Waves

CHAPTER 16. Waves and Sound

PHYSICS. Waves & Simple Harmonic Motion

Introduction to Waves & Sound

CH 17 - MECHANICAL WAVES & SOUND. Sec Mechanical Waves

Today: waves. Exam Results, HW4 reminder. Chapter 8: Wave Motion. What is moving? Energy transport. Motion of a piece of the rope

Waves Mechanical Waves Amplitude Frequency / Period Wavelength Wave Phases Wave Speed : Wave Basics / Wave Properties

Lesson 14: Simple harmonic motion, Waves (Sections )

CHAPTER 14 VIBRATIONS & WAVES

Parts of Longitudinal Waves A compression

Waves. Kevin Small or

Practice Problems For 1st Wave Exam

Defined as a transfer of energy, in the form of a temporary disturbance of a medium, where the medium itself does not move.

The physicist's greatest tool is his wastebasket Albert Einstein

Physics Waves & Sound

Chapter 16. Waves and Sound

2 nd Term Final. Revision Sheet. Students Name: Grade: 10 A/B. Subject: Physics. Teacher Signature

PHYSICS - CLUTCH CH 16: WAVES & SOUND.

Section 1 Types of Waves. Distinguish between mechanical waves and electromagnetic waves.

Section 1 Types of Waves

4.4 WAVE CHARACTERISTICS 4.5 WAVE PROPERTIES Student Notes

Standing Waves in a String

NATURE AND PROPERTIES OF WAVES P.1

Wave. 1. Transverse 2. Longitudinal 3. Standing

CH 17 - MECHANICAL WAVES & SOUND. Sec Mechanical Waves

P11 Waves 1 Basics.notebook December 13, 2013

Transverse waves cause particles to vibrate perpendicularly to the direction of the wave's motion (e.g. waves on a string, ripples on a pond).

Ch16Lectures Page 1. Ch16Lectures Thursday, April 16, :22 PM

Transcription:

Sound waves... light waves... water waves...

1S-13 Slinky on Stand Creating longitudinal compression waves in a slinky What happens when you pull back and release one end of the slinky? 4/11/2011 Physics 214 Fall 2010 2

Moving one end of the Slinky back and forth created a local compression where the rings of the spring are closer together than in the rest of the Slinky. The slinky tries to return to equilibrium. But inertia cause the links to pass beyond. This create a compression. Then the links comes back to the equilibrium point due to the restoration force, i.e. the elastic force. The speed of the pulse may depend on factors such as tension in the Slinky and the mass of the Slinky.

Energy is transferred through the Slinky as the pulse travels. The work done in moving one end of the Slinky increases both the potential energy of the spring and the kinetic energy of individual loops. This region of higher energy then moves along the Slinky and reaches the opposite end. There, the energy could be used to ring a bell or perform other types of work. Energy carried by water waves does substantial work over time in eroding and shaping a shoreline.

If instead of moving your hand back and forth just once, you continue to produce pulses, you will send a series of longitudinal pulses down the Slinky. If equal time intervals separate the pulses, you produce a periodic wave. The time between pulses is the period T of the wave. The number of pulses or cycles per unit of time is the frequency f = 1/T. The distance between the same points on successive pulses is the wavelength. A pulse travels a distance of one wavelength in a time of one period. The speed is then the wavelength divided by the period: v T f

The pulse we have been discussing is a longitudinal wave: the displacement or disturbance in the medium is parallel to the direction of travel of the wave or pulse. Sound waves are longitudinal.

A longitudinal wave traveling on a Slinky has a period of 0.25 s and a wavelength of 30 cm. What is the speed of the wave? a) 0.25 cm/s b) 0.30 cm/s c) 1 cm/s d) 7.5 cm/s e) 120 cm/s v f 4 Hz 30 cm 120 cm/s

A longitudinal wave traveling on a Slinky has a period of 0.25 s and a wavelength of 30 cm. What is the frequency of the wave? a) 0.25 Hz b) 0.30 Hz c) 0.83 Hz d) 1.2 Hz e) 4 Hz T 0.25 s f 1 T 1 0.25 s 4 Hz

A wave on a rope is shown below. What is the wavelength of this wave? a) 1/6 m b) 1 m c) 2 m d) 3 m e) 6 m In 6 m, the wave goes through 2 complete cycles. The wavelength (length of one complete cycle) is (6 m)/2 = 3 m.

If the frequency of the wave is 2 Hz, what is the wave speed? a) 1/6 m/s b) 2/3 m/s c) 2 m/s d) 3 m/s e) 6 m/s v f 2 s -1 3 m 6 m/s

As the raised portion of a pulse approaches a given point on the rope, the tension in the rope acquires an upward component. The resulting upward force causes this next segment to accelerate upward, and so on down the rope. The speed of the pulse depends on how fast succeeding segments can be started moving (accelerated). By Newton s second law, this is proportional to the force and inversely proportional to the mass of the segment: A larger tension produces a larger acceleration. The speed of the pulse will increase with the tension and decrease with the mass per unit length of the rope: a F m v F where m L

A rope has an overall length of 10 m and a total mass of 2 kg. The rope is stretched with a tension of 50 N. One end of the rope is fixed, and the other is moved up and down with a frequency of 4 Hz. What is the speed of waves on this rope? a) 5.0 m/s b) 7.07 m/s c) 15.8 m/s d) 50 m/s e) 250 m/s m L 2 kg 10 m 0.2 kg/m = F 50 N 0.2 kg/m 250 m2 /s 2 15.8 m/s

Principle of Superposition: When two or more waves combine, the resulting disturbance or displacement is equal to the sum of the individual disturbances. When the two waves are moving the same way at the same time, they are in phase. The resulting combined wave will be larger (have a greater height). If one wave is moving upward when the other wave is moving downward, the two waves are completely out of phase If the two waves have the same height, the resulting combined displacement will be zero. The result of adding two waves together depends on their phases as well as on their height or amplitude. When waves are in phase, we have constructive interference. When waves are out of phase, we have destructive interference.

Examples of wave superposition

When two waves are traveling in opposite directions, such as when a wave is reflected back on itself, the principle of superposition can be applied at different points on the string. At point A, the two waves cancel each other at all times. At this point, the string will not oscillate at all; this is called a node. At point B, both waves will be in phase at all times. The two waves always add, producing a displacement twice that of each wave by itself. This is called an antinode.

1S-41 Standing Waves in Rope Creating transverse standing waves on heavy cable How might we create different wave patterns on the cable? How is this related to tuning a guitar? BY ADJUSTING THE SPEED OF THE JIGSAW OR THE TENSION IN THE CORD, DIFFERENT STANDING WAVE PATTERNS CAN BE GENERATED BETWEEN THE FIXED ENDS. THOUGH THE WAVELENGTH OF THE STANDING WAVE IS FIXED BY THE LENGTH BETWEEN THE FIXED POINTS, THE FREQUENCY DEPENDS ON THE TENSION IN THE CABLE. YOU TUNE A GUITAR BY CHANGING THIS TENSION. 4/11/2011 Physics 214 Fall 2010 16

4B-01 Standing Waves in a Gas What happens when an acoustic standing wave is introduced in the tube? Effects of acoustic standing wave on air pressure The wave pattern indicates a pressure non-uniformity within the tube. 4/11/2011 Physics 214 Fall 2010 17

This pattern of oscillation is called a standing wave. The waves traveling in opposite directions interfere in a way that produces a standing or fixed pattern. The distance between adjacent nodes or adjacent antinodes is half the wavelength of the original waves. At the nodes, it is not moving at all. At points between the nodes and antinodes, the amplitude has intermediate values.

Quiz: A rope has an overall length of 10 m and a total mass of 2 kg. The rope is stretched with a tension of 50 N. One end of the rope is fixed, and the other is moved up and down with a frequency of 4 Hz. What is the wavelength? a) 0.20 m b) 3.95 m c) 10 m d) 15.8 m e) 25 m/s f v f 15.8 m/s 4 Hz 3.95 m

2024 © sportdocbox.com Privacy Policy | Terms of Service | Feedback