In this paper, a novel design of laser monitoring and sound localization system is proposed. It utilizes
laser to monitor and locate the position of the indoor conversation. In China most of the laser monitors no matter used in
labor in an instrument uses photodiode or phototransistor as a detector at present. At the laser receivers of those facilities,
light beams are adjusted to ensure that only part of the window in photodiodes or phototransistors received the beams.
The reflection would deviate from its original path because of the vibration of the detected window, which would cause
the changing of imaging spots in photodiode or phototransistor. However, such method is limited not only because it
could bring in much stray light in receivers but also merely single output of photocurrent could be obtained. Therefore a
new method based on quadrant detector is proposed. It utilizes the relation of the optical integral among quadrants to
locate the position of imaging spots. This method could eliminate background disturbance and acquired two-dimensional
spots vibrating data pacifically. The principle of this whole system could be described as follows. Collimated laser
beams are reflected from vibrate-window caused by the vibration of sound source. Therefore reflected beams are
modulated by vibration source. Such optical signals are collected by quadrant detectors and then are processed by photoelectric
converters and corresponding circuits. Speech signals are eventually reconstructed. In addition, sound source
localization is implemented by the means of detecting three different reflected light sources simultaneously. Indoor
mathematical models based on the principle of Time Difference Of Arrival (TDOA) are established to calculate the twodimensional
coordinate of sound source. Experiments showed that this system is able to monitor the indoor sound source
beyond 15 meters with a high quality of speech reconstruction and to locate the sound source position accurately.
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