KR930703753A - Optical communication device and method for transmitting information through a single optical waveguide - Google Patents

Abstract

An optical communication device for communicating information includes a continuous wave laser light 30 source and one or more acoustic beams 51 modulated in frequency or amplitude by data. The input of the laser light beam and the acoustic beam to the acoustooptic modulator 50 is to produce an undiffracted laser light beam and one or more diffracted laser light beams 52. The diffracted laser light beam is the frequency shifted to the non-narrowed laser light beam and contains the data to be transmitted.

The diffracted but not beam is combined (60). It is transmitted over the optical fiber to the receiver to demodulate at a distance. The receiver has a photodiode 70, the photodiode heterodyning a beam that is diffracted or not and yields a signal having a frequency of the acoustic beam. Tuning circuit 74 separates the signal, and demodulator 80 restores the transmitted data. Using two such communication devices with a single fiber and allocating an available bandwidth, bidirectional multi-channel communication is achieved.

Description

Optical communication device and method for transmitting information through a single optical waveguide

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

1 is a schematic diagram of a first embodiment of a unidirectional optical communication apparatus according to the present invention, FIG. 2 is a schematic diagram of a first embodiment of a transmitter used in the apparatus of FIG. 1 using only one data channel, and FIG. 5 is a schematic diagram of a first embodiment of a receiver used in the apparatus of FIG. 1 using only one data channel, and FIG. 4 is a schematic diagram of a second embodiment of a transmitter according to the present invention using multiple data channels, FIG. FIG. 6 is a schematic diagram of a second embodiment of a receiver in accordance with the present invention using multiple data channels; FIG.

Claims (72)

Input means for generating an acoustic beam modulated by information with an acoustic beam frequency, light source means for generating a continuous wave laser light beam at a fixed optical frequency, an undiffracted laser light beam and a diffracted laser light beam, Modulated means for receiving a laser light beam, the diffracted laser light beam being frequency shifted from the frequency of the laser light beam not diffracted by the acoustic beam frequency and diffracted through an angle in accordance with the acoustic beam frequency, and in a first position, the combined laser light beam Means for spatially coupling an undiffracted or diffracted laser light beam to generate a signal, and coupled between a first position and a second position to receive a combined laser light beam at a first position and to transmit the combined laser light beam to a second position Receiving a single optical waveguide and, in the second body, a combined laser light beam from the optical waveguide. Optical communication for communicating information from a first position to a second position, comprising output means for demodulating the diffracted laser light beam to generate a demodulated signal at a high acoustic beam frequency and including the information content of the acoustic beam. Device. The optical communication device according to claim 1, wherein the modulation means is an acoustooptic modulator. 2. An optical communication device according to claim 1, wherein the light source means comprises a single laser diode operating in continuous wave mode. 2. An optical communication device according to claim 1, wherein the output means comprises a single photodiode. 5. The optical communication of claim 4, wherein the output means comprises a tuning circuit coupled to the photodiode and tuned to the acoustic beam frequency to generate a demodulated signal. Device. 6. A second to second position as claimed in claim 5, wherein the output means comprises a demodulator connected to the tuning circuit and the demodulator demodulating the demodulated signal to generate an output data signal comprising the information content of the acoustic beam. Optical communication device that communicates information to a location. 7. An optical communication apparatus according to claim 6, wherein the output means comprises a low noise amplifier which amplifies the demodulated signal generated by the tuning circuit before inputting to the demodulator. . 2. The apparatus of claim 1, wherein the input means comprises means for generating a continuous wave signal at an acoustic beam frequency, means for modulating the continuous wave signal with a data signal comprising information to generate a drive signal at an acoustic beam frequency, and And means for responsively generating an acoustic beam from said first position to said second position. The optical communication device of claim 1 wherein the light source means comprises means for aiming a laser light beam. A first position according to claim 1, wherein the means for spatially coupling the non-diffraction or diffracted laser Guam beam comprises a collecting lens for receiving the non-diffraction or diffracted laser hollow beam and generating a combined laser light beam. An optical communication device for communicating information from a to a second location. The method of claim 1, wherein each acoustic beam has a different frequency and is modulated by a separator of information to be communicated by the device, wherein the acoustic beam generated by the input means comprises a plurality of acoustic beams, each diffracted The laser light beam is diffracted by different diffraction angles and frequency shifted by the frequency of the corresponding acoustic beam, the modulating means generating a corresponding plurality of diffracted laser light beams, each demodulated signal having the information content of the corresponding acoustic beam. Wherein the output means demodulates the plurality of diffracted laser light beams to produce a plurality of demodulated signals corresponding to the plurality of acoustic beams, whereby the plurality of separate information channels are simultaneously communicated through a single optical waveguide. And communicating information from the first position to the second position. 12. The optical communications device of claim 11 wherein the modulator means is an acoustic light modulator. 12. An optical communication device according to claim 11, wherein the light source means comprises a single laser diode operating in a continuous wave mode. 12. The optical communication device according to claim 11, wherein the output means comprises a single photodiode. 15. The apparatus of claim 14, wherein the output means comprises a plurality of tuning circuits, each connected to the photodiode and for tuning to the acoustic beam frequency of the other of the plurality of acoustic beams to generate one of the plurality of auxiliary signals. An optical communication device for communicating information from one location to a second location. 16. The demodulator of claim 15, wherein each demodulator demodulates a corresponding one of the plurality of demodulated signals to generate an output signal coupled to one of the tuning circuits and containing information content of the corresponding acoustic beam. And a demodulator for communicating information from the first position to the second position. 17. The apparatus of claim 16, wherein each amplifier amplifies the other of the plurality of demodulated signals before inputting the demodulated signal to a corresponding one of the plurality of demodulators, wherein the output means also includes a plurality of low noise amplifiers. An optical communication device for communicating information from a first location to a second location. 12. The apparatus according to claim 11, wherein the input means each continuous wave signal has a frequency of one of a plurality of acoustic beams, the means for generating a plurality of continuous wave signals and a corresponding acoustic beam for generating a plurality of modulated signals. And means for modulating each continuous wave signal by a separate data signal comprising information content. 16. An optical communication device for communicating information from a first position to a second position. 19. The apparatus of claim 18, wherein the input means comprises means for combining a modulated signal to generate a drive signal in the acoustic frequency band and generating a plurality of acoustic beams in response to the drive signal. Optical communication device for communicating information from a second location to a second location. 12. An optical communication device according to claim 11, wherein the light source means comprises means for aiming a laser light beam. 12. The method of claim 11, wherein the means for spatially combining the non-diffracted or diffracted laser light beam comprises a collecting lens for receiving the non-diffracted or diffracted laser light beam and generating a combined laser beam. Optical communication device for communicating information from a second location to a second location. Each acoustic beam has a different acoustic beam frequency and is modulated by a separator of information to be communicated by the device, an input means for generating a plurality of acoustic beams and a light source means for generating a continuous wave laser light beam at a substantially fixed optical frequency And, as a modulating means for receiving the acoustic beam and the laser light beam and generating an undiffracted laser light beam and a plurality of diffracted laser light beams, each diffracted laser light beam corresponding to one of the plurality of acoustic beams, each of the plurality of diffracted beams The laser light beam is frequency shifted from the frequency of the laser light beam that is not diffracted by the acoustic beam frequency of the corresponding acoustic beam and diffracted through an angle in accordance with the acoustic beam frequency of the corresponding acoustic beam such that each diffracted laser light beam is at a different diffraction angle. Modulating means diffracted by and shifted by a different frequency, in a first position Means for spatially coupling an undiffracted or diffracted laser light beam to generate a laser light beam, coupled between a first position and a second position, the combined laser light beam being received at the first position and coupled to the second position. Output means for demodulating the diffracted laser light beam to receive a single optical waveguide for transmitting a laser light beam and, in a second position, a laser light beam coupled from the optical waveguide to generate a plurality of demodulated signals corresponding to the plurality of acoustic beams. Wherein each demodulated signal has an acoustic beam frequency of a corresponding acoustic beam and includes the information content of the corresponding volume beam, so that the plurality of separate information channels have output means that are simultaneously communicated through a single optical waveguide. An optical communication device for communicating information from a first position to a second position. 23. The optical communication device according to claim 22, wherein the modulating means is an acoustic light modulator. 23. The optical communication device of claim 22, wherein the light source means comprises a single laser diode operating in a continuous wave mode. 23. The optical communication device according to claim 22, wherein the output means comprises a single photodiode. 27. The apparatus of claim 25, wherein the output means further comprises a plurality of tuning circuits, each connected to a photodiode and each tuned to an acoustic beam frequency of another one of the plurality of volume beams to generate one of the plurality of demodulated signals. An optical communication device for communicating information from one location to a second location. 27. The demodulator of claim 26, wherein each demodulator demodulates a corresponding one of the plurality of demodulated signals to generate an output signal coupled to one of the tuning circuits and containing corresponding acoustic beam information content. And an optical communication device for communicating information from the first position to the second position. 28. The apparatus of claim 27, wherein each amplifier amplifies the other of the plurality of demodulated signals before inputting the demodulated signal to a corresponding one of the plurality of demodulators, wherein the output means also includes a plurality of low noise amplifiers. An optical communication device for communicating information from a first location to a second location. 23. The apparatus of claim 22, wherein the input means comprises: means for generating a plurality of continuous wave signals, wherein each continuous wave signal has a frequency of one of a plurality of acoustic beams, and a corresponding acoustic beam for generating a plurality of modulated signals. And means for modulating each continuous wave signal by a separate data signal comprising information content. 16. An optical communication device for communicating information from a first position to a second position. 30. The device of claim 29, wherein the modulated signal is coupled to generate a drive signal in an acoustic frequency band, and wherein the modulating means includes means for generating a plurality of acoustic beams in response to the drive signal. Optical communication device for communicating information from a second location to a second location. 23. The optical communication device of claim 22, wherein the light source means comprises means for aiming a laser light beam. 23. The apparatus of claim 22, wherein the means for spatially combining the undiffracted laser light beam with the diffracted laser light beam comprises a focusing lens that receives the undiffracted laser light beam and the diffracted laser light beam to produce a combined laser light beam. An optical communication device for communicating information from a first position to a second position. A bidirectional optical communication device for communicating information between a first position and a second position, the bidirectional optical communication device comprising: generating a single optical waveguide connected to the first position and the second position, a first acoustic beam modulated by the first information, First input means having a first acoustic beam frequency, first light source means for generating a first continuous wave laser light beam at a constant optical frequency, and a first laser light beam that receives the first acoustic beam and the first laser light beam and is not diffracted And a diffracted first laser light beam, wherein the diffracted first laser light beam is shifted in frequency from the dominant wavelength of the undiffracted first laser light beam by the first acoustic beam frequency, Spatially combining the first modulating means diffracted according to the first acoustic beam frequency, the first non-diffracted laser light beam and the diffracted first laser light beam at a first position to produce a first combined laser light beam, and a second Awards on location First means for directing the first coupled laser light beam to an optical waveguide for transmission of the first coupled laser light beam, and in the second position, receiving the first coupled laser light beam from the optical waveguide and receiving the first diffracted laser light beam; First output means for demodulating and generating a first demodulated signal having a first acoustic beam frequency and including the first information content of the first acoustic beam, and generating a second acoustic beam modulated by the second information and generating a second A second input means having an acoustic beam frequency, a second light source means for generating a second continuous wave laser light beam at a constant second light frequency, and a second laser light beam that receives the second acoustic beam and the second laser light beam and is not diffracted And a diffracted second laser light beam, wherein the diffracted second laser light beam is shifted in frequency from a frequency of the second laser light beam that is not diffracted by the second acoustic beam frequency and at a second angle, that is, the second acoustic beam. frequency Thus spatially combining the second modulating means to be diffracted, and at the second position, the non-diffraction second laser light beam and the diffracted second laser light beam, to generate a second combined laser light beam and to second join the first position. Second means for directing the second light beam coupled to the optical waveguide for transmission of the laser light beam, and receiving at the first position a second combined laser light beam from the optical waveguide and demodulating the second diffracted laser Guam beam; And second output means for generating a second demodulated signal having a two-acoustic beam frequency and comprising a second information content of the second acoustic beam. 34. The bidirectional optical communication device according to claim 33, wherein the first and second modulation means comprise an angular acoustic-optic modulator. 34. The bidirectional optical communication device according to claim 33, wherein the first light source means each comprises a single laser diode operating in continuous wave mode. 36. The bidirectional optical communication device according to claim 35, wherein the laser diode comprises a first light source and a second light source for generating a laser light beam at the same frequency. 34. The bidirectional optical communication device according to claim 33, wherein the first output means and the second output means each comprise a single photodiode. 38. The apparatus of claim 37, wherein the first output means and the second output means are respectively connected to a corresponding photodiode and tuned to a first acoustic beam frequency or a second acoustic beam frequency to produce a first demodulated signal or a second demodulated signal. And a tuning circuit for generating the bidirectional optical communication device. An optical communication apparatus for communicating information from a first position to a second position, comprising: input means for generating a drive signal modulated by the information and having an acoustic frequency, and a single laser diode for generating a continuous wave laser light beam at a constant optical frequency; Receiving a drive signal and generating an acoustic beam at an acoustic frequency, the non-diffracted laser light beam and the diffracted laser light beam including information and in response to the interaction of the acoustic beam with a laser light beam, the diffracted laser light beam Is an acoustic-optic modulator diffracted according to an acoustic frequency, i.e., the frequency shifted from the frequency of the laser light beam that is not diffracted by the acoustic frequency, and in the first position, the non-diffracted laser light beam and the diffracted laser light beam Means for generating a combined laser light beam, the first position and the second position And receive a combined laser light beam at a first position, receive a combined laser light beam at a first position, and receive a combined laser light beam from the optical fiber at a second position and act as an optical heterodyne. And demodulate the diffracted laser light beam, the unit comprising a single photodiode having an acoustic frequency and generating a demodulated signal comprising the information content of the acoustic beam. A method of optically communicating information from a first position to a second position, the method comprising: generating an acoustic beam modulated by the information and having an acoustic beam frequency, generating a continuous wave laser light beam at a constant frequency; Receives the beam and the laser light beam to produce an undiffracted laser light beam and a diffracted laser light beam, the diffracted laser light beam being an angle at which the frequency is shifted from the frequency of the undiffracted laser light beam by the acoustic beam frequency, ie acoustic Diffracting according to the beam frequency, spatially combining the non-diffracted laser light beam and the diffracted laser light beam at a first position to generate a combined laser light beam, and receiving the combined laser light beam at the first position A single optical waveguide connected between a first position and a second position for transmitting a laser light beam coupled to a second position is provided. Receiving a combined laser light beam from the optical waveguide at a second position and demodulating the diffracted laser light beam to generate a demodulated signal having an acoustic and frequency and containing information content of the acoustic beam. Optical communication method, characterized in that. 41. The method of claim 40, wherein generating the non-diffracted laser light beam and the diffracted laser light beam comprises directing the laser light beam and the acoustic beam at a lateral angle through an acoustic-optic modulator. . 41. The method of claim 40, wherein generating the laser light beam comprises operating a single laser diode in continuous wave mode. 41. The method of claim 40, wherein demodulating the diffracted laser light beam comprises irradiating a single photodiode with a combined laser light beam. 44. The method of claim 43, wherein demodulating the diffracted laser light beam includes applying a output signal of the photodiode to a tuning circuit tuned to an acoustic beam frequency to generate a demodulated signal. The method of claim 40, wherein the generating of the acoustic beam comprises generating a continuous wave signal having an acoustic beam frequency, modulating the continuous wave signal by a data signal including information, and generating a driving signal at an acoustic beam frequency. Generating an acoustic beam in response to the signal. An optical communication apparatus for communicating information from a first position to a second position, comprising: input means having an acoustic beam frequency modulated by the information, the light source means generating a continuous wave laser light beam at a fixed optical frequency; Receiving an acoustic beam and a laser light beam to produce an undiffracted laser light beam and a diffracted laser light beam, the diffracted laser light beam being at an angle at which the frequency is shifted from the frequency of the laser light beam that is not diffracted by sound and frequency, ie Modulating means diffracted in accordance with the acoustic beam frequency, means for spatially combining the non-diffracted laser light beam and the diffracted laser light beam at a first position to generate a combined laser light beam, and a laser light beam coupled at the first position. Transmission means for receiving and transmitting a laser light beam coupled to the second position, and at the second position, the transmitted Optical device, characterized in that receiving a laser light beam, by demodulating the diffracted laser light beams, including output means for generating a demodulated signal having the acoustic beam frequency comprising the information content of the acoustic beam. 47. The optical communication device according to claim 46, wherein the modulation means is an acoustic-optic modulator. 47. An optical communication device according to claim 46, wherein said light source means comprises a single laser diode operating in continuous wave mode. 47. An optical communication device according to claim 46 wherein the output means comprises a single photodiode. 50. The optical communication device according to claim 49, wherein said output means further comprises a tuning circuit connected to the photodiode and generating a demodulated signal tuned to an acoustic beam frequency. 51. The optical communication apparatus as set forth in claim 50, wherein said output means further comprises a demodulator connected to the tuning circuit and demodulating the demodulated signal to generate an output data signal including the information content of the acoustic beam. 53. The optical communication apparatus as set forth in claim 51, wherein said output means includes a low noise amplifier for amplifying a demodulated signal generated by a tuning circuit before inputting to said demodulator. 47. The apparatus of claim 46, wherein the input means comprises: means for generating a continuous wave signal having an acoustic beam frequency, means for generating a drive signal having an acoustic beam frequency by modulating the continuous wave signal with a data signal comprising information; And means for generating an acoustic beam in response to the signal. 47. An optical communication device according to claim 46, wherein the light source means comprises means for aiming a laser light beam. 47. The optical communication device of claim 46, wherein the means for spatially combining the diffracted or unlased laser light beams comprises a collimating lens that receives the diffracted or unlased laser light beams and generates a combined laser light beam. 47. The apparatus of claim 46, wherein the acoustic beams generated by the input means comprise a plurality of acoustic beams, each acoustic beam being modulated by a separator of information to be communicated by the device with a different frequency, the modulation means corresponding to Generating a plurality of diffracted laser light beams, each diffracted laser light beam being diffracted by a different diffraction angle and frequency shifted by a frequency of a corresponding acoustic beam, the output means demodulating the plurality of diffracted laser light beams Generating a plurality of demodulated signals corresponding to the acoustic beams, wherein each demodulated signal includes information content of the corresponding acoustic beam, and the plurality of separate information channels are communicated simultaneously. 57. The optical communication device according to claim 56, wherein the modulation means is an acoustooptic modulator. 57. An optical communication apparatus according to claim 56, wherein said light source means comprises a single laser diode operating in continuous wave mode without being modulated by information. 57. An optical communication device according to claim 56 wherein the output means is a single photodiode. 60. The apparatus of claim 59, wherein the output means comprises a plurality of tuning circuits, each tuning circuit connected to a photodiode, tuned to a different one of the plurality of acoustic beams, and generating one of the plurality of demodulated signals. Optical communication device, characterized in that. 61. The apparatus according to claim 60, wherein said output means further comprises a plurality of demodulators, each demodulator connected to each of a plurality of demodulation circuits, and demodulating a corresponding signal of the plurality of demodulated signals to thereby reproduce the information content of the corresponding acoustic beam. Optical communication device, characterized in that for generating an output signal comprising a. 62. The apparatus of claim 61, wherein the output means further comprises a plurality of low noise amplifiers, each amplifier amplifying a different one of the plurality of demodulated signals before inputting the demodulated signal to a corresponding demodulator of the plurality of demodulators. An optical communication device. 60. The apparatus of claim 59, wherein the input means comprises means for generating a plurality of continuous wave signals, each continuous wave signal having a frequency of one of the plurality of acoustic beams and comprising information content of a corresponding acoustic beam. Means for modulating each continuous wave signal by a signal to generate a plurality of modulated signals. 64. The optical communication device according to claim 63, wherein said input means comprises means for combining a signal modulated to generate a drive signal in an acoustic frequency band and generating a plurality of acoustic beams in response to said drive signal. 60. An optical communication apparatus according to claim 59, wherein said light source means comprises means for aiming a laser light beam. 60. The optical communication device of claim 59, wherein the means for spatially combining the non-diffraction and diffracted laser light beams comprises an aiming lens for receiving the non-diffraction and diffracted laser light beams to receive the combined laser light beam. A bidirectional optical communication apparatus for communicating information between a first location and a second location, comprising: transmission means for transmitting laser light between a first location and a second location, and having a first sound beam frequency and having first information. First input means for generating a modulated first acoustic beam, first light source means for generating a first continuous wave laser light beam at a substantially fixed first optical frequency, and the diffracted first laser light beam comprises a first sound beam A frequency shifted from the frequency of the first laser light beam undiffracted by frequency, diffracted through a first angle according to the first acoustic beam frequency, and undiffracted by receiving the first acoustic beam and the first laser light beam A first modulating means for generating a first laser light beam and a diffracted first laser light beam, and a non-diffraction and diffracted first laser light beam to spatially combine to generate a first combined laser light beam, wherein the first location is a second place. Combined laser light beam First means for directly transmitting the first combined laser light beam to a transmitting means at a first location, receiving the transmitted first combined laser light beam and demodulating the first diffracted laser light beam, the first acoustic beam First output means for generating a first demodulated signal having a frequency and including a first information content of the first acoustic beam at a second location, and a second modulated by second information having a second acoustic beam frequency Second input means for generating an acoustic beam, second light source means for generating a second continuous wave laser light beam at a substantially fixed second optical frequency, and diffracted second laser light beam are non-diffracted by a second acoustic beam frequency A second laser light beam and diffracted by being frequency-shifted from the frequency of the second laser light beam, diffracted through a second angle according to the second incidence beam frequency, and receiving a second acoustic beam and a second laser light beam To generate a second laser light beam The second modulating means and the non-diffraction and diffracted second laser light beams are spatially combined to generate a second combined laser light beam, and to the transmission means for transmitting the second combined laser light beam to a first location. Second means for directly transmitting the combined laser light beam at a second location, and receiving the transmitted second combined laser light beam to demodulate a second diffracted laser light beam, said second sound beam having a second acoustic beam frequency and And second output means for generating a second demodulated signal comprising the second information content of said first location. 68. The communications device of claim 67 wherein each of the first and second modulation means is an acoustooptic modulator. 68. The communications device of claim 67, wherein each of the first and second light source means comprise a single laser diode operating in a continuous wave mode. 70. The communications device of claim 69, wherein the laser diode having the first and second light sources generates a laser light beam at substantially the same frequency. 68. The communications apparatus of claim 67 wherein each of the first and second output means comprises a single photodiode. 72. A communication device as claimed in claim 71, wherein each of the first and second output means comprises a tuning circuit connected to a corresponding photodiode and tuned to the first or second acoustic beam frequency to generate a first or second demodulated signal. Device. ※ Note: The disclosure is based on the initial application.