Chapter 14 Notes Vibrations and Waves. Section 14.1 Objectives Use Hooke’s law to calculate the force exerted by a spring. Calculate potential energy.

Slides:

Advertisements

Similar presentations

Chapter 11 Vibrations and Waves.

Advertisements

Chapter 14 Vibrations and Wave.

Chapter 13 Vibrations and Waves.

Vibrations and Waves Chapter 12.

Waves Physics H.

Warm-Up: January 30, 2012 Where do we encounter waves? Write down all the examples of waves that you can think of.

Objectives Identify the conditions of simple harmonic motion.

Chapter 13 Vibrations and Waves.

Vibrations and Waves Chapter 11.

Holt Physics Chapter 11 Vibrations and Waves Simple Harmonic Motion Simple Harmonic Motion – vibration about an equilibrium position in which a restoring.

Chapter 11 Elasticity And Periodic Motion. Goals for Chapter 11 To follow periodic motion to a study of simple harmonic motion. To solve equations of.

Harmonic Motion and Waves Chapter 14. Hooke’s Law If an object vibrates or oscillates back and forth over the same path, each cycle taking the same amount.

Herriman High Honors Physics Chapter 11 Vibrations and Waves.

Hr Physics Chapter 11 Notes

Vibrations and Waves Chapter 11.

Section 1 Simple Harmonic Motion

For this section we start with Hooke’s Law. But we already learned this. (partially)

Chapter 12: Vibrations and Waves Section 1: Simple harmonic motion Section 2: Measuring simple harmonic motion Section 3: Properties of waves Section 4:

Daily Challenge, 10/2 Give 3 examples of motions that are periodic, or repeating.

16-6 Wave Speed on a Stretched String

For this section we start with Hooke’s Law. But we already learned this. (partially)

Chapter 11:Vibrartions and Waves

Waves – Chapter 10.2 – 10.5 Transverse vs longitudinal Frequency f, wavelength, period T, wave speed – v = f Harmonic waves: y(x) = Asin(kx); with k =

Chapter 11 Preview Objectives Hooke’s Law Sample Problem

Wave Mechanics Physics 1. What is a wave? A wave is: an energy-transferring disturbance moves through a material medium or a vacuum.

Chapter 12: Vibration and Waves 12.1 Simple Harmonic Motion.

CP Physics Chapter 12 Waves. Hooke’s Law F spring = kx During the periodic motion At equilibrium, velocity reaches a maximum (b) At maximum displacement,

Waves and Energy Transfer

Lecture Outline Chapter 13 College Physics, 7 th Edition Wilson / Buffa / Lou © 2010 Pearson Education, Inc.

Chapter 11 Vibrations and Waves.

Chapter 12 VibrationsandWaves. Chapter 12 Objectives Hooke’s Law Hooke’s Law Simple Harmonic Motion Simple Harmonic Motion Elastic Potential Energy Elastic.

ALSO CALLED SIMPLE HARMONIC MOTION PERIODIC MOTION.

 How do you find the amplitude of a pendulum?  In simple harmonic motion, where is the velocity highest/lowest? Acceleration? Force?  What is the period?

Example: pulse on a string speed of pulse = wave speed = v

Chapter 14 Vibrations and Waves. Periodic Motion Motion which repeat in a regular cycle Simple Harmonic Motion Occurs if the restoring force is proportional.

Chapter 14 Vibrations and Waves Periodic Motion Periodic motion- motions which repeat in a regular cycle Simple harmonic motion- when the force.

Chapter 13: Vibrations and Waves

Vibrations & Waves Chapter 25 - This will be phun!

Chapter 11 Preview Objectives Hooke’s Law Sample Problem

Preview Objectives Hooke’s Law Sample Problem Simple Harmonic Motion The Simple Pendulum Chapter 11 Section 1 Simple Harmonic Motion.

Chapter 11: Harmonic Motion

For a standing wave to be set up in a string there has to be two waves travelling in it. Explain what has to be the same and what has to be different about.

Springs Hooke’s Law (Fs) Spring Constant (k)

Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Chapter 11 Simple Harmonic Motion Simple harmonic motion =periodic.

© Houghton Mifflin Harcourt Publishing Company The student is expected to: Chapter 11 Section 1 Simple Harmonic Motion TEKS 7A examine and describe oscillatory.

Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Chapter 11.

Copyright © by Holt, Rinehart and Winston. All rights reserved. ResourcesChapter menu Chapter 11.

Holt Physics Chapter 12 Waves.

Vibrations and Waves Physics I. Periodic Motion and Simple Harmonic Motion  Periodic Motion - motion that repeats back and forth through a central position.

Simple Harmonic Motion Repeated motion with a restoring force that is proportional to the displacement. A pendulum swings back and forth. pendulum A spring.

Plan for Today (AP Physics 1)

Simple Harmonic Motion

Section 1 Simple Harmonic Motion

How to Use This Presentation

Vibrations and Waves Chapter 13.

How to Use This Presentation

AP Physics B, Waves Vibrations and Waves

CHAPTER 12 Vibrations and Waves

Constant Force (F = constant)

Also called simple harmonic motion

Section 1 Simple Harmonic Motion

Vibrations and Waves Chapter 12.

Mechanical Waves A mechanical wave is a physical disturbance in an elastic medium. Consider a stone dropped into a lake. Energy is transferred from stone.

11-3: PROPERTIES OF WAVES.

11-3: PROPERTIES OF WAVES.

Physics A First Course Vibrations, Waves, and Sound Chapter 20.

Physics A First Course Vibrations, Waves, and Sound Chapter 20.

Section2 :Wave Properties Wave: disturbance that carries energy

Chapter 14 Notes Vibrations and Waves.

Presentation transcript:

Chapter 14 Notes Vibrations and Waves

Section 14.1 Objectives Use Hooke’s law to calculate the force exerted by a spring. Calculate potential energy of an elastic spring. Identify objects in simple harmonic motion. Determine variables that affect the period of a pendulum. Describe the affect of resonance on an object.

Periodic Motion Examples – clock pendulum, vibrating guitar string

Simple Harmonic Motion Described by two quantities: – Period – Amplitude

Hooke’s Law

Potential Energy in a Spring

Example Problem A spring stretches by 18 cm when a bag of potatoes weighing 56 N is suspended from its end. a.Determine the spring constant. b.How much elastic potential energy is stored in the spring when it is stretched this far?

Pendulums

Example Problem How long must a pendulum be on the Moon, where g=1.6 m/s 2, to have a period of 2.0 s?

Resonance

Section 14.2 Objectives Differentiate between transverse and longitudinal waves. Determine wave speed, wavelength, and frequency using corresponding equations.

Mechanical Waves Types – Transverse – Longitudinal – Surface

Transverse Waves

Longitudinal Waves

Surface Waves

Measuring a Wave Speed Amplitude Wavelength Phase Period Frequency

Example Problem A sound wave has a frequency of 192 Hz and travels the length of a football field, 91.4 m, in s. a)What is the speed of the wave? b)What is the wavelength of the wave? c)What is the period of the wave? d)If the frequency was changed to 442 Hz, what would be the new wavelength and period?

Section 14.3 Objectives Relate a wave’s speed to the medium in which the wave travels. Describe the motion of a wave as it encounters boundaries. Apply the principle of superposition to wave interference.

Waves at Boundaries

Free boundary – waves/free.cfm waves/free.cfm Fixed boundary – waves/fix.cfm waves/fix.cfm

Superposition of Waves Interference – Constructive – Destructive waves/U10L3c.cfm waves/U10L3c.cfm

Standing Waves