1 / 15

Standing waves on a string (review)

Standing waves on a string (review). n=1,2,3. Different boundary conditions: Both ends fixed (see above) Both ends free (similar to both ends fixed ) One end fixed and on end free (next slide). n=1. n=3. Standing waves on a string (review). One end fixed and on end free.

ursa
Télécharger la présentation

Standing waves on a string (review)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Standing waves on a string (review) n=1,2,3... • Different boundary conditions: • Both ends fixed (see above) • Both endsfree (similar to both ends fixed) • One end fixed and on end free (next slide)

  2. n=1 n=3 Standing waves on a string (review) One end fixed and on end free

  3. Standing waves in tubes (longitudinal) • Waves in tubes (pipes) can be described in terms of: • displacement vibrations of the fluid • pressure variations in the fluid • A pressure node is a displacement antinode and vice versa Open and both ends closed pipes Closed (both ends): displacement pressure Open: pressure displacement n=1 n=2 n=3

  4. Nodes at 0.0 m and 0.4 m One end open pipes (stopped pipes) displacement pressure n=1 n=3 Example: Standing sound waves are produced in a pipe that is 0.6 m long. For the first overtone, determine the locations along the pipe (measured from the left end) of the displacement nodes. The pipe is closed at the left end and open at the right end.

  5. Sound Acoustic waves in the range of frequencies: 20Hz -20,000Hz • Sound waves: • can travel in any solid, liquid or gas • travel faster in a medium that is more dense • in liquids and gases sound waves are longitudinal ONLY! • longitudinal and transversal sound waves could propagate in in solids Sound in air is a longitudinal wave that contains regions of low and high pressure Pressure sensor Vibrating tuning fork These pressure variations are usually small – a “loud” sound changes the pressure by 2.0x10-5 atm

  6. Speed of Sound Speed of waves in strings (review): Speed of sound waves: B is bulk modulus, defined as is density Speed of sound waves in a gas: is ratio of heat capacities, is the equilibrium pressure of the gas

  7. Example: Speed of Sound in Air

  8. Speed of Sound in Some Common Substances Substance Speed (m/s) 1. Air (20 oC) 344 2. Helium 1,006 3. Water 1,140 4. Lead 1,200 5. Human tissue 1,540 6. Aluminum 5,100 7. Iron and steel 5,200

  9. Pressure variations

  10. Example: Displacement Wave Amplitude of Sound in Air

  11. piano note Properties of Sound - A “pure tone” is a sound with a sinusoidal waveform. - This is a sound with a single frequency; produced by tuning fork, etc. We classify sounds according to their waveforms: - A “complex tone” is a sound that repeats itself but is not sinusoidal Most sounds are like this! A note from a musical instrument will be mostly sinusoidal, but have a character all its own that is specific to the instrument. “Noise” is sound with a complex waveform that does not repeat No definite wavelength or frequency

  12. Perception of Sound 1. Pitch. 2. Loudness. 3. Tone quality. 1. The pitchof a sound is how “high” or “low” we perceive a sound to be (directly related to how we perceive frequency); combinations of notes that are “pleasing” to the ear have frequencies that are related by a simple whole-number ratio (Pythagoras) We use three qualities to characterize how we perceive sound: 2. The loudness of a sound is how we perceive the amplitude of the sound wave The unit of sound loudness is the decibel (dB) Quiet: 30 dB; Moderate: 50 dB; Noisy: 70 dB; Very loud: 90 dB; Problems: 120 dB 3. The tone quality of a sound is how we distinguish sounds of the same pitch and loudness (how we perceive the qualities of the waveform)

  13. Musical Instruments Stringed musical instruments produce sound by vibrating a wire or string Anything that causes pressure vibrations creates sound! A plucked string on a guitar produces a different sound than a violin The tension in the string is used to adjust the wave speed and the frequency Wind instruments produce sound by pressure waves in a tube The sound reflects partly at the open end Valves change the effective length of the tube

  14. Complex Waves To produce a pure fundamental tone on a guitar string: Pluck a guitar string in the middle: Fourier Theorem: The initial shape is a superposition of the sinusoidal shapes for the fundamental mode and for higher harmonics. The sound produced is the fundamental frequency plus higher harmonics. Different musical instruments sound different even when playing the same tone partly because the harmonic contents are different. Pull the template away fast. Then the string will vibrate in its fundamental mode.

  15. Fourier Analysis

More Related