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Longitudinal Standing Waves  Consider a tube with both ends opened  If we produce a sound of frequency f 1 at one end, the air molecules at that end.

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Presentation on theme: "Longitudinal Standing Waves  Consider a tube with both ends opened  If we produce a sound of frequency f 1 at one end, the air molecules at that end."— Presentation transcript:

1 Longitudinal Standing Waves  Consider a tube with both ends opened  If we produce a sound of frequency f 1 at one end, the air molecules at that end are free to vibrate and they vibrate with f 1  The amplitude of the wave is the amplitude of the vibrational motion (SHM) of the air molecule – changes in air density  Similar to the transverse wave on a string, a standing wave occurs if the length of the tube is a ½- multiple of the wavelength of the wave

2  For the first harmonic (fundamental), only half of a cycle is contained in the tube  Following the same reasoning as for the transverse standing wave, all of the harmonic frequencies are  Identical to tranverse wave, except number of nodes is different Open-open tube string Open-open tube

3  An example is a flute. It is a tube which is open at both ends. xx LaLa LbLb mouthpiece  We can also have a tube which is closed at one end and opened at the other (open-closed)  At the closed end, the air molecules can not vibrate – the closed end must be a ``node’’  The open end must be an anti-node

4  The ``distance’’ between a node and the next adjacent anti-node is ¼ of a wavelength. Therefore the fundamental frequency of the open-closed tube is  The next harmonic does not occur for ½ of a wavelength, but ¾ of a wavelength. The next is at 5/4 of a wavelength – every odd ¼ wavelength  Note that the even harmonics are missing. Also, Open-closed

5 Complex (Real) Sound Waves  Most sounds that we hear are not pure tones (single frequency – like the fundamental f 1 of a standing wave)  But are superpositions of many frequencies with various amplitudes  For example, when a note (tone, frequency) is played on a musical instrument, we actually hear all of the harmonics (f 1, f 2, f 3, …), but usually the amplitudes are decreased for the higher harmonics  This is what gives each instrument it’s unique sound

6  For example, the sound of a piano is dominated by the 1 st harmonic while for the violin, the amplitudes of the 1 st, 2 nd, and 5 th harmonic are nearly equal – gives it a rich sound String fixed at both ends and the open-open tube Open-open tube Summary Violin wave form

7 Example: Problem 17.38 A tube with a cap on one end, but open at the other end, produces a standing wave whose fundamental frequency is 130.8 Hz. The speed of sound is 343 m/s. (a) If the cap is removed, what is the new fundamental frequency? (b) How long is the tube? Solution: Given: f 1 oc =130.8 Hz, n=1, v=343 m/s

8 (a) We don’t need to know v or L, since they are the same in both cases. Solve each equation for v/L and set equal (b) Can solve for L from either open-open or open- closed tubes

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