AP Physics B, Waves Vibrations and Waves

Slides:



Advertisements
Similar presentations
Chapter 14 Vibrations and Wave.
Advertisements

Simple Harmonic Motion
Chapter 11 Waves. Waves l A wave is a disturbance/oscillation generated from its source and travels over long distances. l A wave transports energy but.
Waves Energy can be transported by transfer of matter. For example by a thrown object. Energy can also be transported by wave motion without the transfer.
Wave Properties Chapter 14.
Chapter 13 VibrationsandWaves. Hooke’s Law F s = - k x F s = - k x F s is the spring force F s is the spring force k is the spring constant k is the spring.
Review Game. The distance from the peak of a wave to the adjacent wave is the _____. a) amplitude b) wavelength Answer: b) wavelength.
Vibrations and Waves Chapter 12.
Simple Harmonic Motion
Chapter 11 Vibrations and Waves. n Simple Harmonic Motion A restoring force is one that moves a system back to an equilibrium position. Example: mass.
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.
Holt Physics Chapter 11 Vibrations and Waves Simple Harmonic Motion Simple Harmonic Motion – vibration about an equilibrium position in which a restoring.
Vibration and Waves AP Physics Chapter 11.
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.
Barry Latham Physics: Principles & Problems Glencoe Science, 2005.
Herriman High Honors Physics Chapter 11 Vibrations and Waves.
Hr Physics Chapter 11 Notes
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.
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.
Chapter 11: Vibrations and Waves Periodic Motion – any repeated motion with regular time intervals.
For this section we start with Hooke’s Law. But we already learned this. (partially)
© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.
Chapter 11 Vibrations and Waves. Units of Chapter 11 Simple Harmonic Motion Energy in the Simple Harmonic Oscillator The Period and Sinusoidal Nature.
Vibrations and Waves. Periodic Motion u Motion that follows the same path over equal time intervals u Include orbiting planets, moons, vibrating objects,
Copyright © 2009 Pearson Education, Inc. Lecture 1 – Waves & Sound b) Wave Motion & Properties.
Chapter 11 Preview Objectives Hooke’s Law Sample Problem
Wave Motion. Conceptual Example: Wave and Particle Velocity Is the velocity of a wave moving along a cord the same as the velocity of a particle of a.
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,
Oscillations About Equilibrium. 7.1 Periodic Motion.
Hooke’s Law F s = - k x F s is the spring force k is the spring constant It is a measure of the stiffness of the spring A large k indicates a stiff spring.
© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.
Lecture Outline Chapter 13 College Physics, 7 th Edition Wilson / Buffa / Lou © 2010 Pearson Education, Inc.
Lecture Outline Chapter 13 College Physics, 7 th Edition Wilson / Buffa / Lou © 2010 Pearson Education, Inc.
Chapter 12 VibrationsandWaves. Chapter 12 Objectives Hooke’s Law Hooke’s Law Simple Harmonic Motion Simple Harmonic Motion Elastic Potential Energy Elastic.
Vibrations and Waves Chapter 12. Simple Harmonic Motion A motion that occurs repeatedly, vibrating back and forth over its equilibrium point. The force.
Chapter 14 Vibrations and Waves. Periodic Motion Motion which repeat in a regular cycle Simple Harmonic Motion Occurs if the restoring force is proportional.
Vibrations and Waves Waves Periodic Motion Periodic motion – a motion that repeats in a regular cycle. Simple harmonic motion – results when.
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
Oscillations About Equilibrium. 7.1 Periodic Motion.
Chapter 11 Vibrations and Waves.
Chapter 11 Preview Objectives Hooke’s Law Sample Problem
Springs Hooke’s Law (Fs) Spring Constant (k)
Chapter 21 – Mechanical Waves A PowerPoint Presentation by Paul E. Tippens, Professor of Physics Southern Polytechnic State University © 2007.
Chapter 15: Wave Motion 15-2 Types of Waves: Transverse and Longitudinal 15-3 Energy Transported by Waves 15-4 Mathematical Representation of a Traveling.
Holt Physics Chapter 12 Waves.
Simple Harmonic Motion Simple harmonic motion (SHM) refers to a certain kind of oscillatory, or wave-like motion that describes the behavior of many physical.
Vibrations and Waves Physics I. Periodic Motion and Simple Harmonic Motion  Periodic Motion - motion that repeats back and forth through a central position.
Chapter 14 Vibrations and Waves. Hooke’s Law F s = - k x F s is the spring force k is the spring constant It is a measure of the stiffness of the spring.
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)
Waves Chapter 12.
Simple Harmonic Motion
College Physics, 7th Edition
Chapter Six, Seven and Eight
Lecture 11 WAVE.
Section 1 Simple Harmonic Motion
Vibrations and Waves.
Unit 10: Part 1 Waves.
Vibrations and Waves Chapter 13.
Vibrations and Waves Physics I.
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.
Chapter 14 Notes Vibrations and Waves.
Presentation transcript:

AP Physics B, Waves Vibrations and Waves AP Physics B Chapter 13 Vibrations and Waves Marcopul-Pandya, 2006-2007

Periodic Motion Periodic Motion is said to occur when an object vibrates or oscillates over the same path again and again. Examples: springs and pendulums Simple Harmonic Motion is a special form of periodic motion in which the restoring force is proportional to the displacement of the object. It occurs when the net force along the direction of the motion is a Hooke’s law type of force Examples: springs

Definitions Amplitude – maximum displacement of an object from it’s equilibrium point. Cycle – one complete “to-and-fro” motion. Period – time required to complete one cycle. Frequency – number of cycles completed each second. Recall:

Hooke’s Law` Hooke's law is a principle of physics that states that the force  needed to extend or compress a spring by some distance  is proportional to that distance. That is: where  is a constant factor characteristic of the spring, its stiffness. Hooke's law: the force is proportional to the extension.

Equations that are associated with Hooke’s Law  

Elastic Potential Energy  

Elastic Potential Energy  

Motion of a Pendulum A simple pendulum is another mechanical system that exhibits periodic motion Ft= -mgsinФ

Finding Period To find the period of an pendulum in SHM, you can simply use the following equation: To find the period of an ideal spring in SHM, you can simply use the following equation:

AP Physics B, Waves Equations of SHM Marcopul-Pandya, 2006-2007

Wave Motion Mechanical Wave – wave that travels through a medium. There are two types of mechanical waves. Transverse – object particles move perpendicular to the wave’s motion. Longitudinal – object particles move parallel to the wave’s motion. Link to: The Institute of Sound and Vibration Research.

Dissecting a Wave crest (peak) l A l A l trough Link to ISVR

Fixed Point When the wave strikes a fixed point, Wave Reflection Fixed Point When the wave strikes a fixed point, Free Point When the wave strikes a free point, the wave becomes inverted. the wave remains erect.

Wave Transmission When transmitting to a less dense material: Frequency remains the same. Velocity increases. Wavelength increases. Reflected wave is small. Transmitted wave is big. When transmitting to a more dense material: More of the wave will be reflected back along the lighter cord. Frequency still remains the same. Velocity and wavelength decrease.

Reflection of Wave Fronts Two- or three-dimensional waves travel along wave fronts. The motion of these waves can be seen using rays drawn perpendicular to each wave front. Law of reflection – angle of incidence equals angle of reflection.

Link to ISVR Interference Principle of Superposition – when two waves overlap, the resultant displacement will be the algebraic sum of their separate displacements. Constructive Interference – waves are in phase Destructive Interference – waves are out of phase

Standing Waves Standing wave – when reflected waves are in phase with incident waves and the wave appears to stand still. Fundamental Mode or Frequency – frequency at which a standing wave of the lowest resonance can be produced. Resonant Frequencies – frequencies at which standing waves are produced.

Resonant Frequencies L Node Anti-node Link to ISVR AP Physics B, Waves Marcopul-Pandya, 2006-2007

Sample Problem A mass of 4 kg can stretch a spring by 0.5 m. Determine the spring constant of the spring. A slingshot consists of a light leather cup containing a stone that is pulled back against two rubber bands. It takes 30 N to stretch the bands 1.0 cm A) What is the potential energy stored in the bands when a 50 g stone is placed in the cup and pulled back 0.20 m from the equilibrium position B.) What speed does the stone leave the slingshot.

AP Physics B, Waves Sample Problem A device used to test guitar strings hangs a mass off the end of a string, and then sends waves throughout the string at a rate of 120 Hertz (cycles/second) to determine if the string has the correct mass to length ratio. For a particular string, a mass is hung over a pulley that is 0.6 meters away, and hanging a mass of 4 kg creates a standing wave with 6 loops. Determine the m/L ratio of the string. Marcopul-Pandya, 2006-2007