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The Problem:
To detect sound within a room (having an outside window) at a distance. There are several methods that might accomplish this, with some fidelity; [1] however this page will describe the use of a LASER Microphone. The use of a LASER to transduce sound from a window pane/glass is commonly used in movies which leave the mistaken impression that any such task is easy and the LASER Microphone, itself, is highly portable and easily set up. My recent experience is just the opposite. |
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There are several forms the LASER Mic can take; the several that
follow are, by no means all:
1)_ The one that is probably the most intuitive is a system that "grazes" a LASER beam at an angle to the plane of the glass (e.g., 45-deg.), with the photo detector at a complementary angle, and located at a near distance on the other side of the window, see fig. 1. The principle being that sound vibrations will cause the window glass to move sufficient to deflect the LASER beam across the receiving photo detector. |
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2)_ The second method might be the same as above, with the difference being the LASER and detector are co-located; either with a slight angle between the incident beam and the reflected beam; or boresighted where the incident and reflected beam share the same superimposed. | ||||||||||||
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(0° Angular, or Grazing Detection) |
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By using Interferometry, one stands the best chance for success (fidelity wise). However, the difficulty of use has increased somewhat. Also, this particular approach has several deficienses--the most glaring (sorry) one is the very large differences in the "leg" length. Ideally both legs of an interferometer should be of equal length. This is due to temporal or longitudinal coherence: where the phase coherence of a LASER beam changes over time. If the two jointly arriving beams are not synchronized the constructive and destructive interference is degraded, or nonexistent, thus limiting the device's sensitivity. | ||||||||||||
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3)_ A third approach might be
to use an interferometer. This takes the form of
fig. 3, except one of the "arms" of the interferometer is the long path to and from the window. This, of course, suffers "coherence degradation," as explained above. |
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4)_ The final approach is an interferometer
similar to the one above, but having both legs of equal length--the so
called "Dual Beam LASER Mic."
The main principle is the differential measurement of glass movement (acoustic vibration) across a small section of the glass pane. This has the advantages of ~equal leg length for temporal coherence;
common mode rejection of gross window movements, and some rejection of
commom-mode path disterbances.
Note: There is nothing magic about the
LASER's Wave Length. The bound being between visible (e.g., < 670-nm),
and Infrared (e.g., >1500-nm) or Far-Infrared. The ideal WL is what is
termed the "NIR," (Near-Infra-Red) band.
There are only a finite number of WLs available
in this band, i.e., it's a Physics thing. Often the determining
factor is cost and ease of use. Speaking of which, alignment can be a Bitch
if you can't see the beam. So while experimenting, you might consider
using a visible
LASER!
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Suggested Optical Configuration | ||||||||||||
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Circuit has Wide Dynamic Range
PIN Diode detector can be substituted with less expensive devices. |
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| Q:
I would like to make an optical microphone using your method , but there is a thing that i don't understand (my teacher too): in the dual beam microphone, if both legs of the interferometer are on the window, they vibrate together, and there is no path difference?! (or just a little phase difference) and it would not be possible to get the frequency of the vibration. Could you explain to me if i'm wrong ? it would REALLY help me out. How could I realized one? Does it worked well?
A:
There are several other things that complement this situation:
2) The speed of sound in air is ~ 1100 ft/sec, in glass the speed of sound is in the neighborhood of ~20,000 ft/sec. I have tested this method, it Does Work. While experimenting, you might Seriously
Consider using a visible
RED LASER!
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| Misc Notes:
Finding the components for this and other projects: In the majority of cases, in today's consumer market, it is significantly cheaper to purchase either new or used devices and cannibalize them for the parts. Also, and more importantly, this assures you of not being the victim
of promises not kept by parts vendors.
In the case of the LASER microphone, finding an inexpensive red LASER pointer, of which there are many, would be a good starting point. As for photo detectors, capable of detecting reflected LASER light, with voice frequencies impressed on it, TV remote control detectors (that reside in the TV set) might be a good source. As I mention on this page, if possible use a RED visible LASER; as oppose to using an invisible Near Infrared (NIR) LASER. Alignment is a bitch if you can't see the LASER light!! Of course, once you have perfected the system, then you can substitute
the invisible NIR LASER.
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