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Describing Waves traveling disturbances § 14.1–14.2.

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1 Describing Waves traveling disturbances § 14.1–14.2

2 What’s a Wave? Oscillation –object moves cyclically Wave –medium moves cyclically –disturbance travels, medium does not

3 Group Whiteboard Work 2.A wave generator produces 10 pulses each second. The pulses travel at 300 cm/s. a.What is the period of the waves? b.What is the wavelength of the waves?

4 Wave Pulse Why does the pulse move? What determines its speed? What happens inside the medium?

5 Points to Ponder The particles of the string change their motion as the wave travels. What force accelerates them? ac b d What are the velocity and acceleration of the string particles at the following positions? Why? a.middle (leading edge) b.crest c.middle (trailing edge) d.trough

6 Types of Waves Motion of the medium is perpendicular to the direction the wave travels: transverse wave (example: string wave) Motion of the medium is parallel to the direction the wave travels: longitudinal wave (examples: sound wave, slinky wave) Animation

7 Wave Speed Speed of disturbance traveling through the medium Generally not the speed of the oscillating medium itself!

8 Periodic Waves repeat in time and space § 15.2

9 Wavelength: crest-crest distance Trough: low point Period: crest-crest-timing Features of a Wave Crest: high point crest trough

10 Periodic Wave Parameters Angular frequency =  (rad/s) Cycle frequency f =  /2  (cycle/s) Repeat time = period T = 1/f (s/cycle) Repeat distance = wavelength (m/cycle) Angular wavenumber k = 2  / (rad/m) Wave speed v = /T = f =  /k (m/s)

11 Poll Question Doubling the frequency of a wave while keeping its speed constant will cause its wavelength to A.increase. B.decrease. C.stay the same.

12 Poll Question Doubling the frequency of a wave while keeping its wavelength constant will cause its speed to A.increase. B.decrease. C.stay the same.

13 Poll Question Doubling the wavelength of a wave while keeping its speed constant will cause its period to A.increase. B.decrease. C.stay the same.

14 Propagation Speed in a rope § 14.2

15 Purely transverse wave In a rope, string, or spring: Speed increases with tension F Speed decreases with density  v = F/ 

16 Wave Functions oscillations extended § 14.3

17 Think Question The waves travel to the right.  In which direction is A moving right now? A.A is momentarily stationary. B.Upward.  C.Downward.  AB A and B are points on the medium. C D

18 Poll Question The waves travel to the right.  A and B are points on the medium. In which direction is B moving right now? A.B is momentarily stationary. B.Upward.  C.Downward.  AB C D

19 Think Question The waves travel to the right.  A and B are points on the medium. In which direction is C moving right now? A.C is momentarily stationary. B.Upward.  C.Downward.  AB C D

20 Think Question The waves travel to the right.  A and B are points on the medium. In which direction is D moving right now? A.D is momentarily stationary. B.Upward.  C.Downward.  AB C D

21 Formula Description Displacements y of A and B with time AB y(x A,t) = A cos(  t) y(x A + /4,t) = A cos(  t–2  /4) yAyA yByB t y +A −A generalize to any x

22 Formula Description y(x A,t) = A cos(  t) y(x A + /4,t) = A cos(  t–2  /4) y(x,t) = A cos(  t–kx) same as y(x,t) = A cos(kx–  t) where –k( /4) = –2  /4 k = 2  /

23 Parameters  = 2  /T = angular frequency (rad/s) k = 2  / = wave number (rad/m)

24 Graphing y (x,t) Each tells only part of the story! y (x = 0) y (t = 0) xx tt T snapshot of the wave at one time displacement of the medium at one place

25 3D Graph xx tt crest trough T slope = v Displacement-position-time

26 Traveling the Other Way xx tt crest trough T slope = v Displacement-position-time

27 Wave (Phase) Velocity Where is the wave at any time? Continuity of single y-value (crest, trough, etc.) How does location x giving some y change with time? y = A cos(kx –  t) = constant y kx −  t = constant phase =  x =  t/k +  /k Phase velocity =  x/  t =  /k= /T

28 Wave Equation General solution: y = f(x – vt) Phase travels with velocity v (Disclaimer: Physical waves don’t have to follow this equation, but folks may forget this detail.) 2y2y x2x2 2y2y t2t2 v2v2 1 =

29 What Does It Mean? Acceleration of the medium is directly proportional to its curvature, so Restoring force is directly proportional to distortion. (stiffness matters) 2y2y x2x2 2y2y t2t2 v2v2 1 =

30 What Does It Mean? curvature = (1/v 2 ) a = (1/v 2 ) F/m mv 2 = F/curvature = stiffness v 2 = stiffness/mass (Note similarity to  2 = k/m.) 2y2y x2x2 2y2y t2t2 v2v2 1 =

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