1. Waves

2. What are waves?
A wave is a transfer of energy from one place to another.
Waves take many forms.
Wave Characteristics include:
Amplitude
Wavelength
Frequency
Period
Wave Speed

3. Transverse Waves
particles in the medium vibrate perpendicularly to the motion of the wave
Examples:
water waves
waves on a string
wavelength
crest
amplitude
trough

4. Longitudinal Waves (Compressional Waves)
particles in the medium vibrate parallel to the wave velocity
made up of alternating areas of high density or pressure (compressions) and low density or pressure (rarefactions)
Examples: Sound waves, slinky waves
compression
rarefaction

5. Mechanical Waves Waves that require a medium to transfer energy.
May be either transverse or compressional (longitudinal).
Examples:
Sound waves, water waves, earthquake waves, waves in a string

6. Electromagnetic Waves
Waves that consist of an electric field and a magnetic field working to propagate it through free space (a vacuum)
No medium required
Best modeled using transverse waves
All EM waves travel at the speed of light, c c = 3 x 108 m/s
Electromagnetic waves
Radio, microwaves, infrared, visible light, ultraviolet, x-rays, gamma rays

7. Wave Characteristics and Behaviors

8. Amplitude
Amplitude - the maximum displacement of the medium measured from the rest or equilibrium position.
Depends on the amount of energy carried by the wave.
Crest - highest point on waveform, maximum displacement of medium
Trough - lowest point on waveform, maximum displacement of medium

9. Wavelength, λ
The distance between corresponding points on consecutive waves (crest to crest, compression to compression, etc).
Depends on frequency (inversely related) in a given medium or on speed if changing mediums.

10. Frequency, f
Frequency (f) - the number of complete cycles (or waves) that pass a given point in the medium per time (usually 1 sec).
1 Hertz (Hz) = 1 cycle (wave) / sec.
Stays the same even when the wave goes into a different medium.
Depends only on the rate (or frequency) of the source that is making the waves.

11. Period, T
Period (T) - the time it takes for one complete cycle (or wave) to pass a given point in the medium, or the time that passes before the motion repeats itself. Measured in seconds. Depends on the frequency.
Note: frequency and period are inverses:
f = 1 / T or T = 1 / f

12. Wave Speed, v
Velocity or speed with which the wave travels through a medium, v
Depends only on the medium.
v = f l or v =

13. Reflection
Reflection is the bouncing back of a wave when it encounters a barrier or a boundary between mediums.

14. Reflection from the end of a wave
Reflection from a free end (wave is free to move at the end) – reflects back on same side
Reflection from a fixed end (wave is not free to move at the end) – reflects back inverted

15. Boundaries
When a wave encounters the boundary between two media, some of the wave will be reflected and some will be transmitted.
How much goes each way is determined by the relative densities of the media.
The transmitted waves will always be erect (right side up).
Both the transmitted and the reflected pulses will have a lower amplitude than the original pulse since the energy is split among them.

16. Crossing Boundaries Less Dense to More Dense
When a wave is moving from a less dense medium to a more dense medium, the transmitted wave slows down and the reflected wave is inverted and keeps the same speed. v
Before
Less dense medium
More dense medium
After
v (less)
v (same)
Reflected wave is inverted.
f, v, λ are the same and A is less.
Transmitted wave - f is the same, A is less, v is less, and λ is less.

17. Crossing Boundaries More Dense to Less Dense
When a wave is moving from a more dense medium to a less dense medium, the transmitted wave speeds up and the reflected wave is erect and keeps the same speed. v
Before
More dense medium
Less dense medium
v -same
v - more
After
Reflected wave is erect.
f, v, λ are the same and A is less.
Transmitted wave - f is the same,
A is less, v is more, and λ is more.

18. Interference
When two or more waves occupy the same space in a medium at the same time, they interfere with each other.
The medium’s displacement at that time will be the vector sum of the displacements caused by the individual waves (crest +, trough -).
After the waves pass through each other, they will look the same as they did before they met.

19. Constructive Interference
When two waves interfere in a manner such that the amplitude of the resultant wave is greater than the amplitude of the individual waves.

20. Destructive Interference
When two waves interfere in a manner such that the amplitude of the resultant wave is smaller than the amplitude of the individual waves.
Note: Complete cancellation does not always occur in destructive interference.

21. Standing Waves
Caused by the interference of two identical waves travelling in opposite directions in a medium or by a wave and its reflected wave.
Wave pattern of alternating nodes and antinodes.
Nodes - areas of no displacement of the medium caused by destructive interference
Antinodes - areas of maximum displacement of the medium caused by constructive interference. λ
Note: One wavelength is equal to twice the distance between nodes. λ= 2 dn or dn= λ / 2
Node
Antinode dn

22. Other wave behaviors
Refraction and diffraction will be covered in the optics units
The Law of reflection will also be covered in the optics units

23. Sound Waves

24. Sound Waves
Note:
More details about sound waves will be covered in the next power point (unit).