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Waves Topic 11.1 Standing Waves. v The Formation.

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Presentation on theme: "Waves Topic 11.1 Standing Waves. v The Formation."— Presentation transcript:

1 Waves Topic 11.1 Standing Waves

2 v The Formation

3 When 2 waves of –the same speed –and wavelength –and equal or almost equal amplitudes –travelling in opposite directions meet, a standing wave is formed

4 The standing wave is the result of the superposition of the two waves travelling in opposite directions The main difference between a standing and a travelling wave is that in the case of the standing wave no energy or momentum is transferred down the string

5 A standing wave is characterised by the fact that there exists a number of points at which the disturbance is always zero These points are called Nodes And the amplitudes along the waveform is different In a travelling wave there are no points where the disturbance is always zero, all the points have the same amplitude.

6 At the correct frequency a standing wave is formed The frequency is increased until a different standing wave is formed

7 Resonance If the frequency of the source of a vibration is exactly equal to the natural frequency of the oscillatory system then the system will resonate When this occurs the amplitude will get larger and larger Pushing a swing is an example of resonance Resonance can be useful and harmful

8 Airplane wings, engines, bridges, tall buildings are objects that need to be protected against resonance from external vibrations due to wind and other vibrating objects Soldiers break step when marching over a bridge in case the force which they exert on the bridge starts uncontrollable oscillations of the bridge

9 Resonance and Standing Waves 1.Standing Waves on Strings

10

11 If you take a wire and stretch it between two points then you can set up a standing wave The travelling waves are reflected to and fro between the two ends of the wire and interfere to produce the standing wave This has a node at both ends and an antinode in the middle – it is called the fundamental

12 With this wave the length of the string is equal to half the wave length L = ½  = 2L As v = f Then f = v /  f = v / 2L This is the fundamental frequency of the string (the 1 st harmonic)

13 This is not the only standing wave that can exist on the string The next standing wave is This is called the 2 nd Harmonic L =

14 With this wave the length of the string is equal to the wave length L =  = L As v = f Then f = v /  f = v / L This is the 2 nd Harmonic frequency of the string Notice it is twice the fundamental frequency

15 The next standing wave is L = 3/2 This is called the 3 rd Harmonic

16 With this wave the length of the string is equal to 3/2 of the wave length L =3/2  = 2/3L As v = f Then f = v /  f = v / 2/3L  f = 3v / 2L This is the 3 rd Harmonic frequency of the string Notice it is three times the fundamental frequency

17 Notice that the only constraint is that the ends of the string are nodes. In general we find that the wavelengths satisfy = 2L n Where n = 1,2,3,4……

18 This is the harmonic series The fundamental is the dominant vibration and will be the one that the ear will hear above all the others The harmonics effect the quality of the note It is for this reason that different musical instruments sounding a note of the same frequency sound different (it is not the only way though)

19 Resonance and Standing Waves 2.Standing Waves in Pipes

20 Sound standing waves are also formed in pipes Exactly the same results apply There are two types of pipes –1. Open ended –2. Closed at one end Nodes exist at closed ends Antinodes exists at open ends

21 a) Open Ended Fundamental Frequency (1 st Harmonic) L = /2  = 2L As v = f Then f = v /  f = v / 2L

22 2 nd Harmonic  = L As v = f Then f = v /  f = v / L L =

23 3 rd Harmonic  = 2/3L As v = f Then f = v /  f = v / 2/3L  f = 3v / 2L L = 3/2

24 The harmonics are in the same series as the string series If the fundamental frequency = f Then the 2 nd harmonic is 2f, 3 rd is 3f and the 4 th is 4f… etc

25 b) Closed at one End Fundamental Frequency (1 st Harmonic) L = /4  = 4L As v = f Then f = v /  f = v / 4L

26 Next Harmonic  = 4/3L As v = f Then f = v /  f = v / 4/3L  f = 3v / 4L L = 3/4

27 And the next harmonic  = 4/5L As v = f Then f = v /  f = v / 4/5L  f = 5v / 4L L = 5/4

28 The harmonics are DIFFERENT to the string and open pipe series If the fundamental frequency = f Then there is no 2 nd harmonic The 3 rd is 3f There is no 4 th harmonic The 5 th is 5f

29 Waves Topic 4.3 Standing Waves

30 v The Formation

31 When 2 waves of –the same speed –and wavelength –and equal or almost equal amplitudes –travelling in opposite directions meet, a standing wave is formed

32 The standing wave is the result of the superposition of the two waves travelling in opposite directions The main difference between a standing and a travelling wave is that in the case of the standing wave no energy or momentum is transferred down the string

33 A standing wave is characterised by the fact that there exists a number of points at which the disturbance is always zero These points are called Nodes And the amplitudes along the waveform is different In a travelling wave there are no points where the disturbance is always zero, all the points have the same amplitude.

34 At the correct frequency a standing wave is formed The frequency is increased until a different standing wave is formed

35 Resonance If the frequency of the source of a vibration is exactly equal to the natural frequency of the oscillatory system then the system will resonate When this occurs the amplitude will get larger and larger Pushing a swing is an example of resonance Resonance can be useful and harmful

36 Airplane wings, engines, bridges, tall buildings are objects that need to be protected against resonance from external vibrations due to wind and other vibrating objects Soldiers break step when marching over a bridge in case the force which they exert on the bridge starts uncontrollable oscillations of the bridge

37 Resonance and Standing Waves 1.Standing Waves on Strings

38

39 If you take a wire and stretch it between two points then you can set up a standing wave The travelling waves are reflected to and fro between the two ends of the wire and interfere to produce the standing wave This has a node at both ends and an antinode in the middle – it is called the fundamental

40 With this wave the length of the string is equal to half the wave length L = ½  = 2L As v = f Then f = v /  f = v / 2L This is the fundamental frequency of the string (the 1 st harmonic)

41 This is not the only standing wave that can exist on the string The next standing wave is This is called the 2 nd Harmonic L =

42 With this wave the length of the string is equal to the wave length L =  = L As v = f Then f = v /  f = v / L This is the 2 nd Harmonic frequency of the string Notice it is twice the fundamental frequency

43 The next standing wave is L = 3/2 This is called the 3 rd Harmonic

44 With this wave the length of the string is equal to 3/2 of the wave length L =3/2  = 2/3L As v = f Then f = v /  f = v / 2/3L  f = 3v / 2L This is the 3 rd Harmonic frequency of the string Notice it is three times the fundamental frequency

45 Notice that the only constraint is that the ends of the string are nodes. In general we find that the wavelengths satisfy = 2L n Where n = 1,2,3,4……

46 This is the harmonic series The fundamental is the dominant vibration and will be the one that the ear will hear above all the others The harmonics effect the quality of the note It is for this reason that different musical instruments sounding a note of the same frequency sound different (it is not the only way though)

47 Resonance and Standing Waves 2.Standing Waves in Pipes

48 Sound standing waves are also formed in pipes Exactly the same results apply There are two types of pipes –1. Open ended –2. Closed at one end Nodes exist at closed ends Antinodes exists at open ends

49 a) Open Ended Fundamental Frequency (1 st Harmonic) L = /2  = 2L As v = f Then f = v /  f = v / 2L

50 2 nd Harmonic  = L As v = f Then f = v /  f = v / L L =

51 3 rd Harmonic  = 2/3L As v = f Then f = v /  f = v / 2/3L  f = 3v / 2L L = 3/2

52 The harmonics are in the same series as the string series If the fundamental frequency = f Then the 2 nd harmonic is 2f, 3 rd is 3f and the 4 th is 4f… etc

53 b) Closed at one End Fundamental Frequency (1 st Harmonic) L = /4  = 4L As v = f Then f = v /  f = v / 4L

54 Next Harmonic  = 4/3L As v = f Then f = v /  f = v / 4/3L  f = 3v / 4L L = 3/4

55 And the next harmonic  = 4/5L As v = f Then f = v /  f = v / 4/5L  f = 5v / 4L L = 5/4

56 The harmonics are DIFFERENT to the string and open pipe series If the fundamental frequency = f Then there is no 2 nd harmonic The 3 rd is 3f There is no 4 th harmonic The 5 th is 5f

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