The present invention provides a tracking sensor and system to maintain the alignment of an optical communication beam between two terminals. A four-quadrant InGaAs photodetector receives the optical beam. Each quadrant of the photodetector transmits the signal to channel circuitry. The channel circ
The present invention provides a tracking sensor and system to maintain the alignment of an optical communication beam between two terminals. A four-quadrant InGaAs photodetector receives the optical beam. Each quadrant of the photodetector transmits the signal to channel circuitry. The channel circuitry synchronously demodulated the signal to calculate received power. The received power for each signal is supplied to an up/down adder, a left/right adder and a total power received adder which provide the relative powers received in the upper half with respect to the lower half and in the left half with respect to the right half as well as the total power received. The fine track mechanism of the receiving terminal is adjusted to equalize the received power for each half. When each half is receiving equal power, the optical beam is centered. The photodetector, channel circuitry, and adders are contained in a single, hermetically sealed package with an optical window through which the optical signal passes.
대표청구항▼
The present invention provides a tracking sensor and system to maintain the alignment of an optical communication beam between two terminals. A four-quadrant InGaAs photodetector receives the optical beam. Each quadrant of the photodetector transmits the signal to channel circuitry. The channel circ
The present invention provides a tracking sensor and system to maintain the alignment of an optical communication beam between two terminals. A four-quadrant InGaAs photodetector receives the optical beam. Each quadrant of the photodetector transmits the signal to channel circuitry. The channel circuitry synchronously demodulated the signal to calculate received power. The received power for each signal is supplied to an up/down adder, a left/right adder and a total power received adder which provide the relative powers received in the upper half with respect to the lower half and in the left half with respect to the right half as well as the total power received. The fine track mechanism of the receiving terminal is adjusted to equalize the received power for each half. When each half is receiving equal power, the optical beam is centered. The photodetector, channel circuitry, and adders are contained in a single, hermetically sealed package with an optical window through which the optical signal passes. fibers with a second optical switch; and coupling said optical transmitter module and said optical monitor to a common systems controller, wherein said systems controller compares the light signal from said optical transmitter module to the light signal detected by said optical monitor and calculates loss characteristic of the optical fiber through which the light signal passed. 2. The method according to claim 1, wherein said optical monitor and said optical transmitter module are at remote locations. 3. The method according to claim 1, further including the step of looping two of said optical fibers together at a remote location, thereby creating a single optical pathway from a first optical fiber and a second optical fiber of said optical fibers. 4. The method according to claim 3, wherein said step of coupling said optical transmitter module to a first end of at least one of said optical fibers includes coupling said first optical switch to the first end of said first optical fiber. 5. The method according to claim 4, wherein said step of coupling said optical monitor to a second end of at least some of said optical fibers, includes coupling said second optical switch to the first end of said second optical fiber. 6. The method according to claim 5, wherein said step of coupling said first optical switch to the first end of said first optical fiber, includes the substeps of: coupling a first wavelength division multiplexer to the first optical fiber; coupling said first optical switch to said wavelength division multiplexer, wherein said first wavelength division multiplexer introduces the light signal to the first optical fiber. 7. The method according to claim 6, wherein said step of coupling said second optical switch, includes the substeps of: coupling said first wavelength division multiplexer to the second optical fiber; coupling said second optical switch to said first wavelength division multiplexer, wherein said first wavelength division multiplexer removes the light signal from the second optical fiber. 8. The method according to claim 5, wherein said step of looping two of said optical fibers together at a remote location, includes coupling a wavelength division multiplexer to the first optical fiber and the second optical fiber at said remote location, wherein said wavelength division multiplexer removes said light signal from the first optical fiber and loops said light signal into the second optical fiber. 9. The method according to claim 1, further including the step of coupling said first optical switch and said second optical switch to said systems controller, wherein said systems controller selectively controls said first optical switch and said second optical switch. 10. The method according to claim 9, wherein said first optical switch and said second optical switch have optical loss values and said systems controller reads said optical loss values from said first optical switch and said second optical switch. 11. A system for testing optical loss characteristics of optical fibers that are received by a specific customer facility through the optical fiber network of a telecommunications provider, said system comprising: an optical transmitter module containing a light source that produces a light signal and an internal monitor for quantifying said light signal; a first optical switch coupled to said optical transmitter module, said first optical switch coupled to at least some of said optical fibers, wherein said first optical switch can selectively direct said light signal to any of the optical fibers connected thereto; an optical monitor for detecting said light signal; a second optical switch coupling said optical monitor to a second end of at least some of said optical fibers, said optical transmitter module and said optical monitor coupled to a common systems controller, wherein said systems controller compares the light signal from said optical transmitter module to the light signal detected by said optical monitor and calculates loss characteristic of the optical fiber through which the light signal passed. 12. The system according to claim 11, wherein said optical monitor and said optical transmitter module are at remote locations. 13. A system for testing optical loss characteristics of optical fibers that are received by a specific customer facility through the optical fiber network of a telecommunications provider, said system comprising: an optical transmitter module containing a light source that produces a light signal and an internal monitor for quantifying said light signal; an optical signal monitor for detecting said light signal; a first wavelength division multiplexer coupled to said pair of optical fibers, said optical transmitter module and said optical signal monitor, wherein said first wavelength division multiplexer introduces said light signal into a first optical fiber of said pair of optical fibers and said first wavelength division multiplexer directs said light signal from a second of said pair of optical fibers to said optical signal monitor; and a second wavelength division multiplexer coupled to said pair of optical fibers, wherein said second wavelength division multiplexer loops said light signal from the first of said pair of optical fibers to the second of said pair of optical fibers. 14. The system according to claim 13, wherein said second wavelength division multiplexer is located at the customer facility. 15. The system according to claim 14, wherein said optical transmitter module and said optical signal monitor are contained within said fiber administration system. 16. The system according to claim 15, further including a second optical switch disposed between said optical signal monitor and said first wavelength division multiplexer. 17. The system according to claim 13, wherein said pair of optical fibers terminate at a fiber administration system in the central office of the telecommunications provider. 18. The system according to claim 13, further including a first optical switch disposed between said optical transmitter module and said first wavelength division multiplexer.
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