1. Sound

2. Loudness and Pitch frequency = pitch Amplitude = volume or intensity
I a A2.
If A doubles I increase by 22 or 4.

3. Standing Wave & Resonance
pattern that results when 2 waves, of same f, & A travel in opposite directions.
Often formed from pulses reflect off a boundary. Waves interfere constructively (antinodes) & destructively (nodes) at fixed points.

4. Standing waves have no net transfer of energy – no direction propagation of energy.

5. Standing Waves form at natural frequencies of the material
Standing Waves form at natural frequencies of the material. Occur when material is at resonance. When system is disturbed it vibrates at many frequencies. Standing wave patterns continue. Other frequencies to die out. Since there is resonance, the amplitude of particular wavelengths/frequencies will be amplified.

6. Relation of Wavelength to String Length for Standing Waves L = 1/2l.

7. l = L.

8. l= L

9. General expression relating wavelength to string length for standing waves:
n ( ½ l) = L
n is a whole number
A whole number of half l’s must fit.

10. Although we would perceive a string vibrating as a whole,
it vibrates in a pattern that appears erratic producing many different overtone pitches. What results are particular tone colors or timbres of instruments and voices.

11. Harmonics
Each standing wave pattern on a string can produce a harmonic.

12. The lowest possible frequency at which a string could vibrate to form a standing wave pattern is known as the fundamental frequency or the first harmonic.

13. 2nd Harmonic

14. Which One??

15. String Length L, l & Harmonics Standing waves can form on a string of length L, when the l can = ½ L, or 2/2 L, or 3/2L etc. Standing waves are the overtones or harmonics. L = nln. n = 1, 2, 3, 4 whole number harmonics. 2

16. Frequencies
Since standing wave forms where ½ l can fit the string exactly, we can calculate f:
Substitute v/f for l.
n = harmonic
Must know speed in material.

17. 1st standing wave forms when l = 2L
First harmonic frequency is when n = 1 as below.
When n = 1, f = v/l . This is fundamental frequency or 1st harmonic.
First harmonic has largest amplitude.

18. For second harmonic n = 2. f2 = v/L
Other standing waves with smaller wavelengths form other frequencies that ring out along with the fundamental.
For second
harmonic n = 2.
f2 = v/L

19. In general, The harmonic frequencies can be found where n = 1,2,3… and n corresponds to the harmonic. v is the velocity of the wave on the string. L is the string length.

20. Pipes and Air Columns

21. closed-pipe resonator
A resonant air column is
simply a standing longitudinal
wave system, much like
standing waves on a string.
closed-pipe resonator
tube in which one end is open
and the other end is closed
open-pipe resonator
tube in which both ends
are open

22. Pipes – the open end has antinode.

23. Standing Waves in Open Pipe Both ends must be antinodes
Standing Waves in Open Pipe Both ends must be antinodes. How much of the wavelength is the fundamental?

24. The 1st harmonic or fundamental can fit ½ l into the tube.
Just like the string L = nl 2
fn = nv 2L
Where n, the harmonic is an integer.

25. Closed Pipe Resonator

26. Closed pipes must have a node at closed end and an antinode at the open end.
How many wavelengths?
L = l 4

27. Here is the next harmonic. How many l’s?
L = 3l 4

28. There are only odd harmonics possible – n = odd number only.
L = 1/4l.
L = 3/4l.
L = 5/4l.
fn = nv where n = 1,3,5 … 4L

29. Application: When waves propagate through a tall building, the building resonates like a tube open at two ends.
What is the equation that relates frequency to wave velocity and building height?

30. The building is 360 m tall and allows waves to travel through it at 2400 m/s, what frequency wave will cause the most damage to it? Explain why. (Hint: What is the resonant frequency)?
3.3 Hz

32. Holt read 13 - 3 pg 509 38 - 39, 41, 44 46, 47 pg 499 #1 – 4 Start in class finish for hwk.

33. Hwk read 491 – 503 do 499 and 503