KR960043622A - Wireless spatial optical communication device of multi wavelength / polarized laser beam - Google Patents

Abstract

The present invention provides an optical communication device that transmits and receives voice, image, computer data, etc. wirelessly without risk of information leakage by using optical characteristics of lasers having different wavelengths and / or polarization states. To this end, the present invention is a signal converter for modulating and amplifying and demodulating a signal to be transmitted and received, a laser driver coupled to the signal converter and converting the converted electrical signal into a laser light signal, combined with the laser driver different wavelengths A laser module having a plurality of lasers for generating a laser signal of a wavelength; a wavelength combining portion coupled to the laser module to match an optical path of laser beams generated from the plurality of lasers; Transmitting and receiving optical unit for transmitting and receiving a matched laser beam through a wireless space, a skin separation unit coupled to the transmission and reception optical unit for separating the received laser beam into a light beam corresponding to each wavelength, and combined with the wavelength separation unit Multi-wavelength level including an optical sensor unit for converting the separated optical signal into an electrical signal It provides a wireless space optical communication device of jeobim.

Description

Wireless spatial optical communication device of multi wavelength / polarized laser beam

Since this is an open matter, no full text was included.

2 is a block diagram of a transmission / reception structure of a spatial optical communication device using a multi-wavelength / multi-polarization laser beam according to the present invention.

Claims (16)

A wireless spatial optical communication apparatus for a multi-wavelength laser beam, comprising: a signal converter configured to modulate and amplify demodulate a signal to be transmitted and received; A laser driver coupled to the signal converter and converting the converted electrical signal into a laser light signal; A laser module having a plurality of lasers coupled to the laser driver to generate laser signals having different wavelengths; A wavelength combiner coupled to the laser module to match an optical path of laser beams generated from the plurality of lasers; A transmission / reception optical unit coupled to the wavelength combiner to transmit and receive a matched laser beam therefrom through a wireless space; A wavelength separation unit coupled to the transmission / reception optical unit to separate the received laser beam into light rays corresponding to each wavelength; And an optical sensor unit coupled to the wavelength separation unit and converting the optical signal separated therefrom into an electrical signal. The light emitting device of claim 1, wherein the wavelength combiner comprises: a beam steering module configured to precisely position an incident angle and a direction to couple the plurality of laser beams into one beam; And optical multiplexing means for receiving a light beam incident by adjusting the incident angle and direction from the beam steering module to generate a single light beam. The apparatus of claim 1, wherein the wavelength separation unit comprises: optical separation means for receiving the multiplexed light rays to generate a plurality of light rays having different wavelengths; And a beam steering module for receiving the light beams separated from the optical separation means and sending the beams to the plurality of lasers. 4. The wireless spatial optical communication device according to claim 2 or 3, wherein the light multiplexing means and the light separating means are prisms. 4. The wireless spatial optical communication apparatus of claim 2 or 3, wherein the light multiplexing means and the light separating means are diffraction gratings. 4. The wireless spatial optical communication apparatus of claim 2 or 3, wherein the optical multiplexing means and the optical separation means are optical fibers. The wireless spatial optical communication device of claim 1, wherein the signal conversion unit comprises a phase inversion circuit having a noise canceling function. The wireless spatial optical communication apparatus of claim 1, wherein the channels of each wavelength support frequency division, time division, and code division schemes. A wireless spatial optical communication device of a multi-polarization laser beam, comprising: a signal converter configured to modulate and amplify a signal to be transmitted and received; A laser driver coupled to the signal converter and converting the converted electrical signal into a laser light signal; A laser module having a plurality of lasers coupled to the laser driver to generate laser signals having different polarizations; A polarization combiner coupled to the laser module to match an optical path of laser beams generated from the plurality of lasers; A transmission / reception optical unit coupled to the polarization coupling unit to transmit and receive a matched laser beam therefrom through a wireless space; A polarization separator coupled to the transmission / reception optical unit to separate the received laser beam into light rays corresponding to each polarization; And an optical sensor unit coupled to the polarization splitter and converting the optical signal separated therefrom into an electrical signal. The method of claim 9, wherein the polarization coupling unit comprises: a beam steering module for precisely positioning an incident angle and a direction to couple the plurality of laser beams into one beam; And optical multiplexing means for receiving a light beam incident by adjusting the angle of incidence and direction from the beam steering module to generate a single light beam. 10. The apparatus of claim 9, wherein the polarization separator comprises: optical separation means for receiving the multiplexed light rays to produce a plurality of light rays having different polarizations; And a beam steering module for receiving the light beams separated from the light separation means and transmitting the beams to the plurality of lasers. 12. The wireless spatial optical communication device according to claim 10 or 11, wherein the light multiplexing means and the light separating means are prisms. 12. The wireless spatial optical communication device according to claim 10 or 11, wherein the light multiplexing means and the light separating means are diffraction gratings. 12. The wireless spatial optical communication device according to claim 10 or 11, wherein the light multiplexing means and the light separating means are optical fibers. The wireless spatial optical communication device of claim 9, wherein the signal conversion unit comprises a phase inversion circuit having a noise canceling function. 10. The apparatus of claim 9, wherein each channel of polarization supports frequency division, time division, and code division. ※ Note: The disclosure is based on the initial application.