Download presentation
Presentation is loading. Please wait.
Published byShannon Ferguson Modified over 9 years ago
1
Chapter 12: Vibrations and Waves Section 1: Simple harmonic motion Section 2: Measuring simple harmonic motion Section 3: Properties of waves Section 4: Wave interactions
2
Simple harmonic motion Simple harmonic motion – vibration about an equilibrium position in which a restoring force is proportional to the displacement from equilibrium. Simple harmonic motion Simple harmonic motion
3
Simple harmonic motion Hooke’s Law Hooke’s Law F elastic = -kx Two examples Mass on a spring Pendulum
4
Simple harmonic motion
5
Measuring simple harmonic motion Amplitude: the maximum displacement from equilibrium. Period (T): the time it takes to execute a complete cycle of motion. Frequency (f): the number of cycles of vibration per unit time. f = 1/T or T = 1/f f = 1/T = 1/20s = 0.05Hz
6
Measuring simple harmonic motion Calculating the Period Simple Pendulum Calculating the Period Mass on a spring
7
Properties of waves Two main classifications of waves Electromagnetic (will study later) Visible light, radio waves, microwaves, and X rays No medium required Mechanical (will study now): a wave that propagates through a deformable, elastic medium Must have a medium Medium: the material through which a disturbance travels
8
Properties of waves Wave Types Pulse wave: a single, nonperiodic disturbance Periodic wave: a wave whose source is some form of periodic motion Usually simple harmonic motion Sine waves describe particles vibrating with simple harmonic motion
9
Properties of waves Parts of a wave Crest The highest point above the equilibrium position Trough The lowest point below the equilibrium Wavelength The distance between two adjacent similar points of the wave, such as crest to crest.
10
Properties of waves Transverse Transverse A wave whose particles vibrate perpendicularly to the direction of wave motion Examples include: water waves and waves on a string Longitudinal Longitudinal A wave whose particles vibrate parallel to the direction of wave motion Sometimes called compression waves Examples include: sound waves, earthquakes, electromagnetic waves
11
Properties of waves Wave speed λ is wavelength For all electromagnetic waves v = 3.00x10 8 m/s For sound waves v = 340 m/s (approximately)
12
Wave interactions Wave interference Constructive interference Interference in which individual displacements on the same side of the equilibrium position are added together to form the resultant wave. Add the two amplitudes to get total amplitude of two new waves
13
Wave interactions Wave interference Destructive interference Interference in which individual displacements on opposite sides of the equilibrium position are added together to form the resultant wave Again add the two amplitudes together. The wave on bottom should be negative however. Wave interference compare Wave interference compare
14
Wave interactions Reflection Reflection Depends on the boundary
15
Wave interactions Standing waves (the wave will appear to be standing still) Standing waves A wave pattern that results when two waves of the same frequency, wavelength, and amplitude travel in opposite directions and interfere Node A point in a standing wave that always undergoes complete destructive interference and therefore is stationary Antinode A point in a standing wave, halfway between two nodes, at which the largest amplitude occurs.
16
Wave interactions Standing waves calculations Must be a node at each end of the string In letter (b) we see that this is ½ a wavelength. Thus for the first standing wave, the wavelength equals 2L In letter (c) we see a complete wavelength. Thus for the second standing wave, the wavelength equals L In letter (d) we see 1½ or 3/2 of a wavelength Thus for the third standing wave, the wavelength equals 2/3 L
17
Wave interactions Practice problem 1 A wave with an amplitude of 1 m interferes with a wave with an amplitude of 0.8 m. What is the largest resultant displacement that may occur?
18
Wave interactions Practice problem 2 A 5 m long string is stretched and fixed at both ends. What are three wavelengths that will produce standing waves on this string?
19
Wave interactions Practice problem 3 A wave with an amplitude of 4 m interferes with a wave with an amplitude of 4.1 m. What will be the resulting amplitude if the interference is destructive? If the interference is constructive?
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.