Physics Level 3 Greymouth High School: 2023

Tuesday 19 September 2023

Week 10 Term 3 2023 Part 3

Homework

Act 4A, p.56 Properties of Waves
Act 5A, p.73-74 Standing Waves
Act 5B, p.79-80 Music
Ex 3D, p.75-79, Standing Waves and Music
Act 6A, p.85-86 The Doppler Effect
Ex 3E, p.81-84, Beats
Ex 3A, p. 50-53 Basic Wave Properties
Ex 3B, p. 57-63 Two Point Source Interference
Ex 3C, p. 66-70 Multi Point Source Interference

Two Point Source Interference

n𝜆 = dsin(𝛳)

Double Slit App - Physics Classroom

Wave-Particle Duality Applied to the Double Slit Experiment

Diffraction Grating of White Light

(Multi-Point Source Interference)

Green vs White Light Diffraction

Multiple Point Source Interference

Thin Film Interference

Making Colour with Holes

Why Blue is so rare

Visible Spectrum

Week 10 Term 3 2023 Part 2

Homework

Act 4A, p.56 Properties of Waves
Act 5A, p.73-74 Standing Waves
Act 5B, p.79-80 Music
Ex 3D, p.75-79, Standing Waves and Music
Act 6A, p.85-86 The Doppler Effect
Ex 3E, p.81-84, Beats

Doppler Effect

The Doppler Effect: what does motion do to waves?

Doppler Effect

Intro to the Doppler Effect

Doppler Effect Observed Frequency Equation

Sonic Boom

Doppler Shifting Song

Beats

two waves of a similar frequency (similar wavelength) superimpose to come in and out of phase causing constructive and deconstructive interference respectively. This causes a warbling/beat sound of frequency (fb) equal to the difference in respective frequencies

fb = | f1 - f2 |

Wave Beats

Easy Beats- Physics

Wine Glass Resonance in Slow Motion

Week 10 Term 3 2023

Homework

Act 4A, p.56 Properties of Waves
Act 5A, p.73-74 Standing Waves
Act 5B, p.79-80 Music
Ex 3D, p.75-79, Standing Waves and Music
Act 6A, p.85-86 The Doppler Effect

Longitudinal Waves

Particle displacement in the medium is parallel to the direction of wave propagation e.g. sound waves, primary earthquake waves

Transverse Waves
Particle displacement in the medium is perpendicular to the direction of wave propagation e.g. light and other electromagnetic waves, secondary earthquake waves

Frequency - Period

Sound Waves

Superposition of Waves

Waves travel through each other and the total amplitude at any moment is equal to the sum of amplitudes of the individual waves.

Standing Waves
In musical instruments - when a reflected wave travels back through itself causing fixed points of Nodes (Deconstructive Interference) and Antinodes (Constructive Interference) due to the fractional relationship between the wavelength (𝜆) of the wave and the length (L) of the resonating chamber

in musical instruments - when a reflected wave travels back through itself causing fixed points of Nodes (Deconstructive Interference) and Antinodes (Constructive Interference) due to the fractional relationship between the wavelength (𝜆) of the wave and the length (L) of the resonating chamber

Harmonic
String
Double Open Ended Pipe
Closed Ended Pipe
1st
𝜆 = 2L
f = f1st
𝜆 = 2L
f = f1st
𝜆 = 4L
f = f1st
2nd
𝜆 = L
f = 2f1st
𝜆 = L
f = 2f1st

3rd
𝜆 = ⅔ L
f = 3f1st
𝜆 = ⅔ L
f = 3f1st
𝜆 = 4/3 L
f = 3f1st
4th
𝜆 = ½ L
f = 4f1st
𝜆 = ½ L
f = 4f1st

5th
𝜆 = ⅖ L
f = 5f1st
𝜆 = ⅖ L
f = 5f1st
𝜆 = ⅘ L
f = 5f1st
Table of Musical Notes and Frequencies

Standing Waves Part I: Demonstration

Standing Waves Part II: Explanation

Standing Waves

Standing Waves on a String

1st Harmonic
2nd Harmonic
3rd Harmonic
4th Harmonic
𝜆 = 2L
𝜆 = L
𝜆 = ⅔ L
𝜆 = ½ L
f = f1st
f = 2f1st
f = 3f1st
f = 4f1st

Standing Waves in a Pipe

Standing Waves in a Wave Tank

Standing Waves on a 2D Plate

Cymatics

Acoustic Levitation in ULTRA SLOW MOTION

Timbre

Timbre is caused by the shape of the repeating wave unit. This gives instruments their characteristic sound even when playing the same note

Musical Notes and Frequencies

("Middle C" is C₄ )

Note	Frequency (Hz)	Wavelength (cm)
C₀	16.35	2109.89
C^#₀/D^b₀	17.32	1991.47
D₀	18.35	1879.69
D^#₀/E^b₀	19.45	1774.20
E₀	20.60	1674.62
F₀	21.83	1580.63
F^#₀/G^b₀	23.12	1491.91
G₀	24.50	1408.18
G^#₀/A^b₀	25.96	1329.14
A₀	27.50	1254.55
A^#₀/B^b₀	29.14	1184.13
B₀	30.87	1117.67
C₁	32.70	1054.94
C^#₁/D^b₁	34.65	995.73
D₁	36.71	939.85
D^#₁/E^b₁	38.89	887.10
E₁	41.20	837.31
F₁	43.65	790.31
F^#₁/G^b₁	46.25	745.96
G₁	49.00	704.09
G^#₁/A^b₁	51.91	664.57
A₁	55.00	627.27
A^#₁/B^b₁	58.27	592.07
B₁	61.74	558.84
C₂	65.41	527.47
C^#₂/D^b₂	69.30	497.87
D₂	73.42	469.92
D^#₂/E^b₂	77.78	443.55
E₂	82.41	418.65
F₂	87.31	395.16
F^#₂/G^b₂	92.50	372.98
G₂	98.00	352.04
G^#₂/A^b₂	103.83	332.29
A₂	110.00	313.64
A^#₂/B^b₂	116.54	296.03
B₂	123.47	279.42
C₃	130.81	263.74
C^#₃/D^b₃	138.59	248.93
D₃	146.83	234.96
D^#₃/E^b₃	155.56	221.77
E₃	164.81	209.33
F₃	174.61	197.58
F^#₃/G^b₃	185.00	186.49
G₃	196.00	176.02
G^#₃/A^b₃	207.65	166.14
A₃	220.00	156.82
A^#₃/B^b₃	233.08	148.02
B₃	246.94	139.71
C₄	261.63	131.87
C^#₄/D^b₄	277.18	124.47
D₄	293.66	117.48
D^#₄/E^b₄	311.13	110.89
E₄	329.63	104.66
F₄	349.23	98.79
F^#₄/G^b₄	369.99	93.24
G₄	392.00	88.01
G^#₄/A^b₄	415.30	83.07
A₄	440.00	78.41
A^#₄/B^b₄	466.16	74.01
B₄	493.88	69.85
C₅	523.25	65.93
C^#₅/D^b₅	554.37	62.23
D₅	587.33	58.74
D^#₅/E^b₅	622.25	55.44
E₅	659.25	52.33
F₅	698.46	49.39
F^#₅/G^b₅	739.99	46.62
G₅	783.99	44.01
G^#₅/A^b₅	830.61	41.54
A₅	880.00	39.20
A^#₅/B^b₅	932.33	37.00
B₅	987.77	34.93
C₆	1046.50	32.97
C^#₆/D^b₆	1108.73	31.12
D₆	1174.66	29.37
D^#₆/E^b₆	1244.51	27.72
E₆	1318.51	26.17
F₆	1396.91	24.70
F^#₆/G^b₆	1479.98	23.31
G₆	1567.98	22.00
G^#₆/A^b₆	1661.22	20.77
A₆	1760.00	19.60
A^#₆/B^b₆	1864.66	18.50
B₆	1975.53	17.46
C₇	2093.00	16.48
C^#₇/D^b₇	2217.46	15.56
D₇	2349.32	14.69
D^#₇/E^b₇	2489.02	13.86
E₇	2637.02	13.08
F₇	2793.83	12.35
F^#₇/G^b₇	2959.96	11.66
G₇	3135.96	11.00
G^#₇/A^b₇	3322.44	10.38
A₇	3520.00	9.80
A^#₇/B^b₇	3729.31	9.25
B₇	3951.07	8.73
C₈	4186.01	8.24
C^#₈/D^b₈	4434.92	7.78
D₈	4698.63	7.34
D^#₈/E^b₈	4978.03	6.93
E₈	5274.04	6.54
F₈	5587.65	6.17
F^#₈/G^b₈	5919.91	5.83
G₈	6271.93	5.50
G^#₈/A^b₈	6644.88	5.19
A₈	7040.00	4.90
A^#₈/B^b₈	7458.62	4.63
B₈	7902.13	4.37

Harmonic	String	Double Open Ended Pipe	Closed Ended Pipe
1st	𝜆 = 2L f = f1st	𝜆 = 2L f = f1st	𝜆 = 4L f = f1st
2nd	𝜆 = L f = 2f1st	𝜆 = L f = 2f1st
3rd	𝜆 = ⅔ L f = 3f1st	𝜆 = ⅔ L f = 3f1st	𝜆 = 4/3 L f = 3f1st
4th	𝜆 = ½ L f = 4f1st	𝜆 = ½ L f = 4f1st
5th	𝜆 = ⅖ L f = 5f1st	𝜆 = ⅖ L f = 5f1st	𝜆 = ⅘ L f = 5f1st

1st Harmonic	2nd Harmonic	3rd Harmonic	4th Harmonic
𝜆 = 2L	𝜆 = L	𝜆 = ⅔ L	𝜆 = ½ L
f = f1st	f = 2f1st	f = 3f1st	f = 4f1st

Tuesday 19 September 2023

Week 10 Term 3 2023 Part 3

Ex 3D, p.75-79, Standing Waves and Music

Ex 3A, p. 50-53 Basic Wave Properties

Ex 3B, p. 57-63 Two Point Source Interference

Ex 3C, p. 66-70 Multi Point Source Interference

Week 10 Term 3 2023 Part 2

Ex 3D, p.75-79, Standing Waves and Music

Week 10 Term 3 2023

Ex 3D, p.75-79, Standing Waves and Music

Longitudinal Waves

Frequency - Period

in musical instruments - when a reflected wave travels back through itself causing fixed points of Nodes (Deconstructive Interference) and Antinodes (Constructive Interference) due to the fractional relationship between the wavelength (𝜆) of the wave and the length (L) of the resonating chamber

Table of Musical Notes and Frequencies

Standing Waves Part I: Demonstration

Acoustic Levitation in ULTRA SLOW MOTION