Adaptive communications focal plane arrays that may be implemented in, e.g., a specially-configured camera that can be utilized to receive and/or process information in the form of optical beams are presented. A specialized focal plane array (FPA) having a plurality of optical detectors is utilized,
Adaptive communications focal plane arrays that may be implemented in, e.g., a specially-configured camera that can be utilized to receive and/or process information in the form of optical beams are presented. A specialized focal plane array (FPA) having a plurality of optical detectors is utilized, where one or more optical detectors are suppressed such that data is not allowed to be output from the one or more suppressed optical detectors, and only a significantly smaller number or subset of optical detectors receiving optical beams are allowed to output data. In this way, the rate at which data is to be output by an adaptive communications FPA (ACFPA) can be significantly reduced.
대표청구항▼
1. A multi-channel adaptive communications focal plane array comprising: a plurality of optical detectors, a subset of which receive one or more optical beams transmitted by one or more optical transmitter assemblies;a plurality of signal discrimination circuits, each of which is operatively connect
1. A multi-channel adaptive communications focal plane array comprising: a plurality of optical detectors, a subset of which receive one or more optical beams transmitted by one or more optical transmitter assemblies;a plurality of signal discrimination circuits, each of which is operatively connected to a corresponding one of the plurality of optical detectors, and performs the following: detects the presence of an optical beam that is currently being received by its corresponding optical detector;computes an estimated signal-to-noise ratio associated with an optical beam it has detected; andsets a value of the estimated signal-to-noise ratio to a set value when it has not detected the presence of the optical beam;a plurality of switching circuits, each of which is operatively connected to a corresponding one of the plurality of optical detectors and a corresponding one of the plurality of signal discrimination circuits, and each of the plurality of switching circuits comprising two or more analog output ports where each analog output port corresponds to a different channel of the multi-channel adaptive communications focal-plane array, wherein each of the plurality of switching circuits performs the following: controls a flow of information being received in the form of an optical beam by either suppressing the flow completely or by outputting the flow to any one of the two or more analog output ports;outputs a location relative to other detectors of the plurality of optical detectors indicative of the corresponding optical detector receiving the optical beam; andoutputs the estimated signal-to-noise ratio provided by its corresponding signal discrimination circuit; andan analog output detector operatively connected to a first of the two or more analog output ports of each of the plurality of switching circuits, the analog output detector informing each of the plurality of switching circuits whether or not information being received by an optical detector from an optical beam is currently being output via the first of the two or more analog output ports of any one of the plurality of switching circuits. 2. The multi-channel adaptive communications focal plane array of claim 1, wherein the plurality of optical detectors are configured in a two-dimensional array. 3. The multi-channel adaptive communications focal plane array of claim 1, wherein each of the plurality of signal discrimination circuits distinguishes between a single optical beam being received by the corresponding optical detector and two or more optical beams simultaneously being received by the corresponding optical detector. 4. The multi-channel adaptive communications focal plane array of claim 1, wherein each of the plurality of signal discrimination circuits outputs an indicator representative of an invalid condition upon a determination that two or more optical beams are simultaneously being received by the corresponding optical detector. 5. The multi-channel adaptive communications focal plane array of claim 1, wherein each of the plurality of switching circuits receives a command initializing an optical beacon receiver mode, and wherein the optical beam comprises an optical beacon. 6. The multi-channel adaptive communications focal plane array of claim 5, wherein the command causes each of the plurality of switching circuits to be disabled, or to remain disabled if one or more of the plurality of switching circuits is already disabled, such that a disabled switching circuit suppresses an output of an electrical signal being produced by its corresponding optical detector, preventing the electrical signal from contributing to the flow of information being output by any output channels of the multi-channel adaptive communications focal plane array. 7. The multi-channel adaptive communications focal plane array of claim 6, wherein one of the plurality of switching circuits becomes enabled for output via its first analog output port when both of the following conditions are simultaneously met: one of the plurality of signal discrimination circuits corresponding to the one of the plurality of switching circuits sends the one of the plurality of switching circuits an estimated signal-to-noise ratio value that is greater than or equal to a minimum signal-to-noise ratio threshold, and the analog output detector informs the one of the plurality of switching circuits that the others of the plurality of switching circuits are all currently suppressing outputs from their respective first analog output ports. 8. The multi-channel adaptive communications focal plane array of claim 7, wherein the one of the plurality of switching circuits remains enabled for output via its first analog output port unless it receives from its corresponding signal-discrimination circuit, a value of the estimated signal-to-noise ratio that is less than the minimum signal-to-noise ratio threshold, such that upon receiving the value of the estimated signal-to-noise ratio less than the minimum estimated signal-to-noise ratio, the one of the plurality of switching circuits is disabled. 9. The multi-channel adaptive communications focal plane array of claim 7, wherein one or more of the plurality of switching circuits whose corresponding optical detectors are neighboring the optical detector to which the one of the plurality of switching circuits that has already been enabled is operatively connected are enabled for output via their respective first analog output ports enhancing the signal strength of the optical beacon. 10. The multi-channel adaptive communications focal plane array of claim 9, wherein the one or more of the optical detectors corresponding to the plurality of switching circuits are determined to be neighboring based upon a focal area centered on the optical detector corresponding to the one of the plurality of switching circuits that has already been enabled for output via its first analog output port. 11. The multi-channel adaptive communications focal plane array of claim 10, wherein the focal area comprises one of a blur circle or blur ellipse, one or more parameters of which depends upon a size of a point-spread function of an imaging lens associated with the multi-channel adaptive communications focal plane array. 12. The multi-channel adaptive communications focal plane array of claim 9, wherein the enabling of the one or more neighboring plurality of switching circuits for output via the first analog output port is initiated by receipt of a signal-to-noise ratio request and a determination that an estimated signal-to-noise ratio output from a corresponding one of the plurality of signal discrimination circuits is greater than or equal to the minimum signal-to-noise ratio threshold. 13. The multi-channel adaptive communications focal plane array of claim 12, wherein the multi-channel adaptive communications focal plane array performs a re-centering procedure to re-center a focal area based upon recent signal-to-noise ratio estimates, the focal area being centered on the optical detector corresponding to the one of the plurality of switching circuits that has already been enabled for output via its first analog output port. 14. The multi-channel adaptive communications focal plane array of claim 1, wherein the multi-channel adaptive communications focal plane array is operatively implemented within an optical receiver assembly, the optical receiver assembly monitoring and processing the optical beacon portion of an optical beam until optical beacon information embedded in the optical beacon is extracted. 15. The multi-channel adaptive communications focal plane array of claim 14, wherein the optical receiver assembly outputs the optical beacon information to an augmented reality device, the augmented reality device presenting one or more aspects of the optical beacon information in an augmented reality presentation displayed to a user of the augmented reality device. 16. The multi-channel adaptive communications focal plane array of claim 15, wherein all of the plurality of switching circuits except one or more of the plurality of switching circuits operatively connected to the one or more of the plurality of optical detectors receiving the optical beam are suppressed by being maintained in a disabled state until the optical beacon information has been extracted from the optical beam. 17. The multi-channel adaptive communications focal plane array of claim 16, wherein another one or more of the plurality of switching circuits operatively connected to another one or more of the plurality of optical detectors receiving another optical beam are enabled while outputs from all of the remaining plurality of switching circuits are suppressed by the remaining plurality of switching circuits being maintained in the disabled state until optical beacon information embedded in the other optical beam has been extracted. 18. The multi-channel adaptive communications focal plane array of claim 1, wherein the optical beam comprises an optical beacon and an optical signal. 19. The multi-channel adaptive communications focal plane array of claim 18, wherein one or more of the plurality of optical detectors, one or more of the plurality of signal discrimination circuits, and one or more of the plurality of switching circuits process the optical beam to extract optical signal information embedded in the optical beam and output it to one of a plurality of output channels of the multi-channel adaptive communications focal plane array upon selection of an augmented reality representation of the optical beacon, and wherein control electronics perform a re-centering procedure periodically during the extraction to re-center a focal area from which the optical signal is being extracted based upon recent signal-to-noise ratio estimates. 20. The multi-channel adaptive communications focal plane array of claim 19, wherein ones of the plurality of switching circuits having corresponding ones of the plurality of optical detectors that are not receiving the optical beam are operationally suppressed during the extraction of the optical signal information. 21. The multi-channel adaptive communications focal plane array of claim 1, wherein analog signals representative of the optical beam output from one or more of the plurality of switching circuits via a subsequently ordered analog output port of each of the one or more of the plurality of switching circuits are combined to create a single analog output in a corresponding channel representative of the optical beam output, wherein the subsequently ordered analog output ports correspond to a total number of channels of the multi-channel adaptive communications focal plane array. 22. The multi-channel adaptive communications focal plane array of claim 21, further comprising digital-signal converters, the total number of which corresponds to the total number of channels of the multi-channel adaptive communications focal plane array, adapted to convert the combined analog signals representative of the optical beam in each of the channels into digital signals representative of the optical beam. 23. The multi-channel adaptive communications focal plane array of claim 22, wherein each of the digital-signal converters transmits the digital signals in each of the channels to an optical receiver assembly. 24. The multi-channel adaptive communications focal plane array of claim 23, wherein optical signal information is simultaneously extracted from two or more different optical beams and simultaneously output via two or more channels.
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