Laser Microphone: Difference between revisions
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Due to the nature of the setups mentioned, we require a decently dim environment to minimise noise, a visible light laser (does not need to be high powered but needs to be decently collimated), an optical bench and corresponding optics equipment to build a Michelson interferometer, a set of photodiodes that can detect the laser light and produce a signal, and an electronic setup that allows us to capture and export the signal from the photodiodes. | Due to the nature of the setups mentioned, we require a decently dim environment to minimise noise, a visible light laser (does not need to be high powered but needs to be decently collimated), an optical bench and corresponding optics equipment to build a Michelson interferometer, a set of photodiodes that can detect the laser light and produce a signal, and an electronic setup that allows us to capture and export the signal from the photodiodes. | ||
== Background == | |||
=== Low-pass filter === | |||
A low pass filter is a filter that passes frequencies lower than a selected cutoff frequency and attenuates signals with frequencies higher than the cutoff. Low-pass filters provide a smoother form of a signal, removing the short-term fluctuations and leaving the longer-term trend. | |||
The cutoff frequency of a low-pass filter is given by | |||
:<math>F = {1 \over 2 \pi RC} </math> | |||
where <math> R </math> is the value of the resistance and <math> C </math> is the value of the capacitance. | |||
===RC filter=== | |||
=== Level (logarithmic quantity) === | |||
A power level is a logarithmic quantity used to measure power, power density or sometimes energy, with commonly used unit decibel (dB). | |||
===Power level=== | |||
Level of a ''power'' quantity, denoted ''L''<sub>''P''</sub>, is defined by | |||
:<math>L_P = \frac{1}{2} \log_{\mathrm{e}}\!\left(\frac{P}{P_0}\right)\!~\mathrm{Np} = \log_{10}\!\left(\frac{P}{P_0}\right)\!~\mathrm{B} = 10 \log_{10}\!\left(\frac{P}{P_0}\right)\!~\mathrm{dB}.</math> | |||
where | |||
*''P'' is the power quantity; | |||
*''P''<sub>0</sub> is the reference value of ''P''. | |||
===Field (or root-power) level=== | |||
The level of a ''root-power'' quantity (also known as a ''field'' quantity), denoted ''L''<sub>''F''</sub>, is defined by | |||
:<math>L_F = \log_{\mathrm{e}}\!\left(\frac{F}{F_0}\right)\!~\mathrm{Np} = 2 \log_{10}\!\left(\frac{F}{F_0}\right)\!~\mathrm{B} = 20 \log_{10}\!\left(\frac{F}{F_0}\right)\!~\mathrm{dB}.</math> | |||
where | |||
*''F'' is the root-power quantity, proportional to the square root of power quantity; | |||
*''F''<sub>0</sub> is the reference value of ''F''. |
Revision as of 08:12, 13 March 2022
A laser spot illuminating a vibrating surface should move along with it, and tracking the motion of the spot should theoretically allow us to retrieve some of the information regarding the vibrations of the surface. If a loud enough sound causes the surface to vibrate, this should theoretically be enough for the transmission of audio information through visual means.
Team Members
Nicholas Chong Jia Le, Marcus Low Zuo Wu
Methods and Requirements
Currently, we intend to attempt this with three different methods.
1. Using a smartphone camera, we try using object tracking and other visual processing techniques to retrieve an audio waveform from a laser spot illuminating a vibrating surface.
2. Using a photodiode / array of photodiodes, we attempt to do the same thing but possibly requiring different signal processing techniques.
3. Using a calibrated Michelson interferometer, we can attempt to detect smaller vibrations to try to retrieve the waveform, this requires more precise optical setup and measurement along with signal processing.
Due to the nature of the setups mentioned, we require a decently dim environment to minimise noise, a visible light laser (does not need to be high powered but needs to be decently collimated), an optical bench and corresponding optics equipment to build a Michelson interferometer, a set of photodiodes that can detect the laser light and produce a signal, and an electronic setup that allows us to capture and export the signal from the photodiodes.
Background
Low-pass filter
A low pass filter is a filter that passes frequencies lower than a selected cutoff frequency and attenuates signals with frequencies higher than the cutoff. Low-pass filters provide a smoother form of a signal, removing the short-term fluctuations and leaving the longer-term trend.
The cutoff frequency of a low-pass filter is given by
where is the value of the resistance and is the value of the capacitance.
RC filter
Level (logarithmic quantity)
A power level is a logarithmic quantity used to measure power, power density or sometimes energy, with commonly used unit decibel (dB).
Power level
Level of a power quantity, denoted LP, is defined by
where
- P is the power quantity;
- P0 is the reference value of P.
Field (or root-power) level
The level of a root-power quantity (also known as a field quantity), denoted LF, is defined by
where
- F is the root-power quantity, proportional to the square root of power quantity;
- F0 is the reference value of F.