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PHY138 – Waves, Lecture 5 Today’s overview

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1 PHY138 – Waves, Lecture 5 Today’s overview
The Principle of Superposition Standing Waves The Guitar: Stringed Instruments The Trumpet: Wind Instruments

2 Message from Dr. Savaria….
If you have a conflict at 6:00-7:30 PM on Dec.5 and wish to write Test 2 at an alternate time: Send an to confirming that you wish to re-register, if you registered for the alternate sitting of Test 1. or Visit April Seeley in MP129 or MP302 to register for the first time you will write in an alternate time. The deadline for confirming / registering is Nov.27 by 5:00PM.

3 Reading Assignment This week’s reading assignment from the text by Knight is: Chapter 21, Sections Suggested Chapter 21 Exercises and Problems for Practice: 7, 19, 25, 31, 49, 65, 71, 83 (skip part b – just use result) Waves Quarter Written Team Problem Set is due Friday by 5:00 PM in T.A. drop box. – You must work in the teams assigned to you in tutorial.

4 Chapter 21: Principle of Superposition
If two or more waves combine at a given point, the resulting disturbance is the sum of the disturbances of the individual waves. Two traveling waves can pass through each other without being destroyed or even altered!

5 Some Results of Superposition:
: Two waves, same wavelength and frequency, opposite direction: Standing Wave : Two waves, same wavelength and frequency, similar direction, different phase: Interference 21.8: Two waves, same direction, slightly different frequency and wavelength: Beats!

6 Standing Wave: The superposition of two 1-D sinusoidal waves traveling in opposite directions.

7 Standing Waves Are a form of “resonance”
There are multiple resonant frequencies called harmonics The boundary conditions and speed of waves determine which frequencies are allowed. The ends of the resonant cavity have forced nodes or antinodes With a wave on a string, it is possible to force an intermediate node

8 Standing Wave in Pressure Forces the Flames higher at antinodes!
OMGWTFBBQ Standing Wave in Pressure Forces the Flames higher at antinodes!

9 Harmonic frequencies Transverse standing wave on a string clamped at both ends: there are nodes in displacement at both ends. Standing sound wave in a tube open at both ends: there are nodes in pressure both ends.

10 Harmonic frequencies Standing sound wave in a tube closed at one end: there is a node in pressure at the open end, and an anti-node at the closed end.

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