Solve Math Simulation for Laser Microphones

  • Thread starter Thread starter Ghassan99
  • Start date Start date
  • Tags Tags
    Laser
AI Thread Summary
The discussion centers on the mathematical simulation for a laser microphone, emphasizing the role of the Gaussian beam equation and the effects of vibrations in the glass pane. Participants debate the modulation type, with some arguing for FM modulation due to the Doppler effect, while others assert that the system typically employs AM modulation through an interferometer. The flexing of the glass is said to cause phase changes that affect the reflected laser beam, which is detected by a photodiode. Clarifications are made regarding the nature of modulation, with consensus leaning towards AM modulation as the more common approach. The conversation highlights the complexities of simulating the laser microphone's operation and the need for a deeper understanding of the underlying physics.
Ghassan99
Messages
17
Reaction score
0
I have been trying to write the mathematical simulation for this device but unfortunately I found no clue to start with .
the simulation should be starting with the Gaussian beam equation of the laser source and then the vibrations in the glass pane cause the window to flex, changing the center of curvature of the window, thereby causing the "focal length(=measure of how strongly the system(glass) converges or diverges light) of the window to change, albeit very slightly. This creates a varying divergence and converges in the reflected laser beam which then can be directed to a photo diode causes the voltage across the detector to fluctuate.
I'm really desperate for a mathematical simulation for this process.
 
Last edited:
Engineering news on Phys.org
Ghassan99 said:
I have been trying to write the mathematical simulation for this device but unfortunately I found no clue to start with .
the simulation should be starting with the Gaussian beam equation of the laser source and then the vibrations in the glass pane cause the window to flex, changing the center of curvature of the window, thereby causing the "focal length(=measure of how strongly the system(glass) converges or diverges light) of the window to change, albeit very slightly. This creates a varying divergence and converges in the reflected laser beam which then can be directed to a photo diode causes the voltage across the detector to fluctuate.
I'm really desperate for a mathematical simulation for this process.

That's not how a laser microphone works. What makes you think it is a modulation in a focal length?
 
that's what I have studied , do you have any other idea i assume?
 
the usual way is that the laser is reflected off the window back to a receiver
The flexing glass FM modulates the laser signal which is then demodulated and the audio recovered

Dave
 
I guess it is possible to build a system based on an optical lensing receiver system with an extremely shallow depth of field such that microscopic defocusing would cause the field to increase enough that the amount of light on a critically sized sensor would vary enough to be detected.

But, I think the more common approach is an interferometer based approach where the reflected signal's phase varies due to the path length changes and is summed with a reference from the transmitter. This produces an AM light signal.
 
hi mebigguy

it may well be AM ... Berkeman PM'ed me with same thoughts
my reasoning for it being FM was that there was a Doppler effect in action which would produce an FM'ing of the laser beam

I don't understand how the laser is AM modulated by a sheet of glass vibrating back and forward ?

cheers
Dave
 
It is an interferometer. The distance to the reflector and back changes as the reflector vibrates. This causes a phase change which is detected by summing with a portion of the transmitted signal.

http://www.williamson-labs.com/laser-mic.htm explains different approaches, including one that is not an interferometer.
 
davenn said:
the usual way is that the laser is reflected off the window back to a receiver
The flexing glass FM modulates the laser signal which is then demodulated and the audio recovered

Dave
mathematically please
 
meBigGuy said:
It is an interferometer. The distance to the reflector and back changes as the reflector vibrates. This causes a phase change which is detected by summing with a portion of the transmitted signal.

http://www.williamson-labs.com/laser-mic.htm explains different approaches, including one that is not an interferometer.

interesting link, saved that one :)

fig 3 is the way I was thinking, but that isn't listed as the interferometer as the others are
So is that one PM, AM or FM or a mixture ?

Dave
 
  • #10
Figure three is just detecting angular deflection of the window the same as figure 2.

It has to work such that the laser light boundary falls through the middle of the detector, and the deflections change the area exposed to the laser. (half the detector is lit with no deflection, all or none with full deflection)

So in principle there is no "modulation" of the light in that application. It is just that the beam is moved off the detector.

BTW, doppler shift of light is not detectible by a photodetector. FM modulation is constant amplitude.
The interferometer actually AM modulates the light intensity. The detector tracks the intensity.
 

Similar threads

A Mode matching to an optical cavity
Replies
0
Views
2K
Two questions about the dynamics of a laser diode
Replies
15
Views
3K
Laser Microphone: Understanding Physics Behind Its Working
Replies
2
Views
4K
Birefringence and Automotive Window Tinting
Replies
9
Views
8K
Mathematica This Week's Finds in Mathematical Physics (Week 241)
Replies
8
Views
4K
Mathematica This Week's Finds in Mathematical Physics (Week 231)
Replies
5
Views
3K
Mathematica This Week's Finds in Mathematical Physics (Week 231)
Replies
5
Views
3K

Hot Threads

Recent Insights

Back
Top