Download presentation
Presentation is loading. Please wait.
Published byCassandra Sullivan Modified over 8 years ago
2
Waves are oscillations and they transport energy. Medium: The matter through which a wave travels 2 Subsets of Waves: Mechanical waves that require a medium to travel through (sound, water, earthquakes) Electromagnetic waves that do not require a medium to travel (light)
3
Most waves are caused by vibrating particles Energy is transported, but the particle simply vibrate in one small area Waves are classified according to the direction in which the particles in the medium move as the wave passes 2 Types: Transverse Longitudinal
4
Transverse Wave Particle motion is perpendicular to the direction of wave motion Examples water waves light waves earthquake S-waves
5
Wavelength = length or size of one full oscillation Amplitude = from sitting wave to a crest Crest = highest point in the wave Trough = Lowest point in the wave Resting State = The very middle, as if there were no waves
6
Remember that the molecules are simply vibrating up and down, NOT moving from one end to the other http://www.ffn.ub.es/~albert/ones/wavemotion.html
7
Longitudinal wave Particle motion is parallel to the direction of wave motion Examples: sound waves earthquake P-waves
8
Compressions – area where the medium is pushed close together Rarefaction – area where the medium is spread further apart
9
Remember that the molecules are simply vibrating left and right, NOT moving from one end to the other http://www.ffn.ub.es/~albert/ones/wavemotion.html
10
wavelength (meters (m)) length or size of one oscillation of a wave v = velocity (m/s) how fast the wave is traveling f = frequency (Hertz (Hz)) How many full wavelengths per second occur
11
Measure from any identical two successive points Symbol for wavelength is lambda( and is measured in meters (m) Oscillation = 1 complete wave cycle There are 4 complete oscillation depicted here 510152025303540 (m)
12
The distance from one crest to the next crest, or from one trough to the next trough. It can be between any two successive points actually! Can exist in a longitudinal wave from one compression to the next compression. We will only concentrate on TRANSVERSE waves.
13
Frequency = number of WAVES passing a stationary point per second Symbol is f Measured in Hertz (Hz)
14
= v/f wavelength (meters (m)) length or size of one oscillation of a wave v = velocity (m/s) how fast the wave is traveling f = frequency (Hertz (Hz)) How many full wavelengths per second occur
15
= v/f The string of a piano that produces the note middle C vibrates with a frequency of 262Hz. If the sound waves produced by this string have a wavelength in air of 1.3m, what is the speed of the sound waves? = v/f 1.3m = v / 262Hz 340.6m/s = v
16
Remember, a wave is just transporting energy! The 2 ways to increase the energy a wave carries. 1) Increase the amplitude of a wave 2) Increase the frequency of a wave (done by decreasing wavelength)
17
http://phet.colorado.edu/sims/wave-on- a-string/wave-on-a-string_en.html http://phet.colorado.edu/sims/wave-on- a-string/wave-on-a-string_en.html
18
http://www.youtube.com/watch?v=z0EaoilzgGE http://www.youtube.com/watch?v=z0EaoilzgGE
19
Change in frequency of a wave due to relative motion between source and observer. A sound wave frequency change is noticed as a change in pitch. Basically, as an object making noise moves closer to you, the pitch of the noise will increase Because the sound waves are compressed upon each other As an object making noise moves away from you, the pitch of the noise will decrease Because the sound waves are further away from each other
20
Sound normally occurs like this from a stationary object With a moving object, the sound being produced is not moving to each side evenly.
21
Sound normally occurs like this from a stationary object
22
Now the object starts slowly moving to the right
23
The object is now traveling right at the speed of sound (340 m/s or 767 mi/hr)
24
The object is now traveling right faster than the speed of sound.
25
http://faraday.physics.utoronto.ca/PVB/Harrison/ Flash/ClassMechanics/Doppler/DopplerEffect.ht ml http://faraday.physics.utoronto.ca/PVB/Harrison/ Flash/ClassMechanics/Doppler/DopplerEffect.ht ml http://galileoandeinstein.physics.virginia.edu/m ore_stuff/flashlets/doppler.htm http://galileoandeinstein.physics.virginia.edu/m ore_stuff/flashlets/doppler.htm
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.