1. Waves Waves are everywhere. Sound waves, visible light waves, radio waves, microwaves, water waves, sine waves, cosine waves, earthquake waves, waves on a string, and slinky waves and are just a few of the examples of our daily encounters with waves.

2. Waves A wave can be described as a disturbance that travels through a medium from one location to another location.

3. The Nature of a Wave Consider the slinky – When a slinky is stretched from end to end and is held at rest, it assumes a natural position known as the equilibrium or rest position.

4. The Nature of a Wave Consider the slinky – To introduce a wave into the slinky, the first coils are displaced or moved from its equilibrium or rest position. The coils might be moved upwards or downwards, forwards or backwards; but once moved, it is returned to its original equilibrium or rest position.

5. The Nature of a Wave Consider the slinky – The act of moving the first coils of the slinky in a given direction and then returning it to its equilibrium position creates a disturbance in the slinky.

6. The Nature of a Wave Consider the slinky – If the first coil of the slinky is given a single back-and- forth vibration, then we call the observed motion of the disturbance through the slinky a pulse. A pulse is a single disturbance moving through a medium from one location to another location.

7. The Nature of a Wave Consider the slinky – The repeating and periodic disturbance which moves through a medium from one location to another is referred to as a wave. – A medium is a substance or material which carries the wave. – Waves are said to be an energy transport phenomenon.

8. Types of Waves A Transverse wave is a wave in which particles of the medium move in a direction perpendicular to the direction which the wave moves. Slinky Demo

9. Types of Waves A Longitudinal wave is a wave in which particles of the medium move in a direction parallel to the direction which the wave moves. Slinky Demo

10. Types of Waves A Surface wave is a wave in which particles of the medium undergo a circular motion. Surface waves are neither longitudinal nor transverse. Video in 3 slides

11. Surface Wave Water Waves – A wave moving across the surface of an ocean, lake, pond or other body of water. The waves are created by some form of a disturbance, such as a rock thrown into the water or a boat moving through the water. The water wave has a crest and a trough and travels from one location to another.

12. Surface Wave In longitudinal and transverse waves, all the particles in the entire bulk of the medium move in a parallel and a perpendicular direction (respectively) relative to the direction of energy transport. In a surface wave, it is only the particles at the surface of the medium which undergo the circular motion.

13. Surface Wave Another view

14. Properties of Waves

15. A Transverse Wave – The crest of a wave is the point on the medium which exhibits the maximum amount of positive or upwards displacement from the rest position. The trough of a wave is the point on the medium which exhibits the maximum amount of negative or downwards displacement from the rest position. Slinky Demo Next

16. Properties of Waves A Transverse Wave – The amplitude of a wave refers to the maximum amount of displacement of a particle on the medium from its rest position on a wave. Slinky Demo

17. Properties of Waves A Longitudinal Wave – A compression is a point on a medium through which a longitudinal wave is traveling which has the maximum density. The amplitude of a longitudinal wave is a measure of how compressed the medium becomes. Slinky Demo Next

18. Properties of Waves A Longitudinal Wave – A rarefaction is a point on a medium through which a longitudinal wave is traveling which has the minimum density. Slinky Demo

19. Properties of Waves Wavelength – The wavelength of a wave is simply the length of one complete wave cycle.

20. Properties of Waves Frequency – The frequency of a wave is the number of complete waves that pass a given point in a certain amount of time. – Frequency is expressed in Hertz (abbreviated Hz) where 1 Hz = 1 cycle/second.

21. Properties of Waves Speed – The speed of a wave is how far a wave travels in one unit of time, or the distance divided by the time. – Speed = Wavelength * Frequency – Or…Frequency = Speed / Wavelength

22. Interaction of Waves

23. Interaction of Waves Reflection – When a wave hits a surface through which it cannot pass, it bounces back

24. Interaction of Waves Angle of Incidence – The angle of incidence is the angle between the incoming wave and an imaginary perpendicular line to the surface.

25. Interaction of Waves Angle of Incidence. The angle of reflection is the angle between the reflection and the imaginary line.

26. Interaction of Waves Refraction – Refraction is seen when a wave moves from one medium to another at an angle, it changes speed as it enters the second medium causing it to bend. Aquarium Demo

27. Interaction of Waves Diffraction – Diffraction is seen when a wave passes a barrier or moves through a hole in a barrier, it bends and spreads out. Wave Tank Demo

28. Interaction of Waves Interference – When two or more waves meet

29. Interaction of Waves Constructive Interference – When two or more waves combine to make a wave with a larger amplitude.

30. Interaction of Waves Destructive Interference – When the amplitudes of two or more waves combine to produce a wave with a smaller amplitude.

31. Making Waves The Pan Flute – A pan flute is a group of tubes with a closed end. Each tube have a different length but, usually, the same diameter of all other tubes. – The length of the tube influence the pitch: longer tubes produce lower notes, shorter tubes produce higher notes. – The inner diameter of the tube influence the speed of blow needed to make the sound audible: smaller diameter means less blow, greater diameter means more blow.

32. Calculating WaveLength Wavelength( ƛ ) is equal to the speed of sound(v) divided by the frequency(f) of the sound. – ƛ = v/fv is in m/s,f is in Hz – ƛ is in meters – v = 346.65m/s (Around room temp)

33. Calculating Tube Length First consider the tube, open on one end, closed on the other…

34. Calculating Tube Length The closed end would be a fixed point…like where the strings attach on a guitar. The open end would be the furthest the wave could swing.

35. Calculating Tube Length So, if I shrink it down……You can see that what was in the tube was only about ¼ of a whole wavelenght.

36. Calculating Tube Length Therefore….the formula for calculating tube length needs to be something like this. – L = v / 4 x f – Where L is in m, – f is in Hz – v = 346.65m/s (Around room temp)

37. Pentatonic Scales The pentatonic scale consists of five notes within one octave without any semitones or tritones. Thus no clashing dissonant intervals. the C major pentatonic (C - D - E - G – A)

38. Pentatonic Scales NoteFrequency (Hz)Wavelength (cm) C261.6132 D293.7117 E329.6105 G392.088.0 A440.078.4