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Waves on a string THIS LECTURE Standing waves Standing waves Dispersive and non-dispersive waves Dispersive and non-dispersive waves.

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Presentation on theme: "Waves on a string THIS LECTURE Standing waves Standing waves Dispersive and non-dispersive waves Dispersive and non-dispersive waves."— Presentation transcript:

1 Waves on a string THIS LECTURE Standing waves Standing waves Dispersive and non-dispersive waves Dispersive and non-dispersive waves

2 Travelling waves x Standing waves No boundaries With boundaries Two ends fixed One end fixed

3 Standing waves Two ends fixed

4 Standing waves Two ends fixed

5 Travelling waves Each section of the string vibrates with same frequency  Each section of the string vibrates with different phase  = kx Each section of the string vibrates with same amplitude A No boundaries x x Standing waves Boundaries 2 2

6 Travelling waves Each section of the string vibrates with same frequency  Each section of the string vibrates with different phase  = kx Each section of the string vibrates with same amplitude A No boundaries x x Standing waves Boundaries Each section of the string vibrates with phase 0 or out of phase by  Each section of the string vibrates with different amplitude 2Asin(k n x) Each section of the string vibrates with same frequency  2 2

7 One end fixed Standing waves

8 Superposition of standing waves

9 Relative intensities of the harmonics for different instruments

10 Playing different instruments x x

11 Dispersive and non-dispersive waves Non-dispersive wave Non-dispersive wave: it does not change shape t = 0 t > 0 Dispersive wave Dispersive wave: it changes shape t = 0 t > 0

12 Two velocities to describe the wave Group velocity, V g Velocity at which the envelope of wave peaks moves Phase velocity, V p Velocity at which successive peaks move For non-dispersive waves V g = V p For dispersive waves V g  V p http://www.isvr.soton.ac.uk/SPCG/Tutorial/Tutorial/Tutorial_files/Web-further-dispersive.htm

13 Group velocity Phase velocity Group and phase velocity Relation between V g and V p dispersive wave If  V p  V g  dispersive wave dispersive wave If  V p = V g  non-dispersive wave

14 Superposition of sinusoidal waves Sinusoidal waves  1, k 1  2, k 2  3, k 3 Superposition Wave-packet

15 Wave propagates with speed c maintaining its shape t = 0 t > 0 Wave changes its shape t = 0 t > 0 Sinusoidal waves have the same speed  1 / k 1 = c  2 / k 2 = c  3 / k 3 = c Non-dispersive wave Sinusoidal waves have different speed  1 / k 1 = c 1  2 / k 2 = c 2  3 / k 3 = c 3 Dispersive wave

16 Ideal string Real string (e.g. a piano string) V p =  /k=c does not depend on k V p =  /k=c depends on k c= slope Dispersion relation c1c1 c2c2 Non-dispersive wave Dispersive wave Waves on a string

17 Ideal string Dispersion relation Real string Group velocity Phase velocity

18 Problem Determine phase and group velocity for waves whose dispersion relation is described by :

19 Group velocity Phase velocity The resulting wave is given by Superposition of sinusoidal waves  k  k

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