Apparatus and method for providing gain equalization
First Claim
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1. A multiple band optical communication system comprising:
- a plurality of optical amplifiers, each operable to receive and amplify at least one of a plurality of communication bands, each communication band comprising a plurality of wavelengths; and
a gain equalizer coupled to at least one of the plurality of optical amplifiers, the gain equalizer operable to receive one of the plurality of amplified wavelengths and to selectively introduce attenuation or gain into each wavelength, the gain equalizer comprising;
a wavelength division demultiplexer operable to separate one or more communication bands into a plurality of wavelengths;
an array of phase shifter stages each comprising;
a micro-electro-optic system (MEMS) device comprising a moveable mirror layer operable to receive a first copy of an input signal from a beam splitter and to reflect the first copy of the input signal for combination with a second copy of the input signal at an output to form an output signal, wherein the first copy of the input signal and the second copy of the input signal comprise unequal amplitudes, the moveable mirror layer displaceable in a substantially piston-like motion to introduce a phase shift between the first and second signal copies at the output, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer; and
a wavelength division multiplexer operable to receive a plurality of phase shifted wavelengths and to multiplex at least some of the phase shifted wavelengths into an optical output signal.
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Abstract
In one aspect of the invention, a gain equalizer comprises a wavelength division demultiplexer operable to separate one or more communication bands into a plurality of wavelengths and an array of phase shifter stages. Each phase shifter stage comprises a micro-electro-optic system (MEMS) device comprising a moveable mirror layer operable to receive a first copy of an input signal from a beam splitter and to reflect the first copy of the input signal for combination with a second copy of the input signal at an output to form an output signal. The moveable mirror layer is displaceable in a substantially piston-like motion to introduce a phase shift between the first and second signal copies at the output, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer. The gain equalizer further comprises a wavelength division multiplexer operable to receive a plurality of phase shifted wavelengths from the second beam splitter and to multiplex at least some of the phase shifted wavelengths into an optical output signal.
38 Citations
36 Claims
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1. A multiple band optical communication system comprising:
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a plurality of optical amplifiers, each operable to receive and amplify at least one of a plurality of communication bands, each communication band comprising a plurality of wavelengths; and
a gain equalizer coupled to at least one of the plurality of optical amplifiers, the gain equalizer operable to receive one of the plurality of amplified wavelengths and to selectively introduce attenuation or gain into each wavelength, the gain equalizer comprising;
a wavelength division demultiplexer operable to separate one or more communication bands into a plurality of wavelengths;
an array of phase shifter stages each comprising;
a micro-electro-optic system (MEMS) device comprising a moveable mirror layer operable to receive a first copy of an input signal from a beam splitter and to reflect the first copy of the input signal for combination with a second copy of the input signal at an output to form an output signal, wherein the first copy of the input signal and the second copy of the input signal comprise unequal amplitudes, the moveable mirror layer displaceable in a substantially piston-like motion to introduce a phase shift between the first and second signal copies at the output, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer; and
a wavelength division multiplexer operable to receive a plurality of phase shifted wavelengths and to multiplex at least some of the phase shifted wavelengths into an optical output signal. - View Dependent Claims (2)
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3. A gain equalizer, comprising:
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a wavelength division demultiplexer operable to separate one or more communication bands into a plurality of wavelengths;
an array of phase shifter stages each comprising;
a first micro-electro-optic system (MEMS) device comprising a moveable mirror layer operable to receive a first copy of an input signal from a first beam splitter and to reflect the first copy of the input signal for combination with a second copy of the input signal at an output port to form an output signal, wherein the first copy of the input signal and the second copy of the input signal comprise unequal amplitudes, the moveable mirror layer displaceable in a substantially piston-like motion to introduce a phase shift between the first and second signal copies at the output port, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer; and
a wavelength division multiplexer operable to receive a plurality of phase shifted wavelengths and to multiplex at least some of the phase shifted wavelengths into an optical output signal. - View Dependent Claims (4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17)
an inner conductive layer disposed inwardly from the moveable mirror layer and forming a space between the moveable mirror layer and the inner conductive layer;
wherein the moveable mirror layer comprises an at least substantially conductive layer operable to move relative to the inner conductive layer in response to a voltage difference between the moveable mirror layer and the inner conductive layer.
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5. The gain equalizer of claim 4, wherein the inner conductive layer comprises a doped semiconductor substrate.
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6. The gain equalizer of claim 4, wherein the inner conductive layer comprises a layer of at least substantially conductive material formed outwardly from a semiconductor substrate.
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7. The gain equalizer of claim 4, wherein the moveable mirror layer comprises a plurality of adjacent mirror strips, at least some of the plurality of adjacent mirror strips separated by air gaps operable to relieve air damping when the mirror strips move relative to the inner conductive layer.
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8. The gain equalizer of claim 7, wherein all of the moveable mirror strips move at least substantially in unison in response to the voltage difference.
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9. The gain equalizer of claim 7, wherein either the inner conductive layer or each of the moveable mirror strips is coupled to a ground, and wherein the other is operable to receive a control voltage signal.
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10. The gain equalizer of claim 4, wherein the moveable mirror layer is operable to facilitate variable attenuation by selectively moving a distance relative to the inner conductive layer, wherein the distance increases as the voltage difference increases.
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11. The gain equalizer of claim 3, further comprising a second micro-electro-optic system (MEMS) comprising a moveable mirror layer operable to receive the second copy of the input signal and to reflect the second copy of the input signal for combination with the first copy of the input signal at the output port to form the output signal, the moveable mirror layer displaceable in a substantially piston-like motion to introduce an additional phase shift between the first and second signal copies at the output port, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer.
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12. The gain equalizer of claim 11, wherein one of the moveable mirror layers is operable to switch from a first position to a second position to lengthen the path length of its associated signal copy through the device, while the other moveable mirror layer is operable to switch from a second position to a first position to shorten the path length of its associated second signal copy through the device.
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13. The gain equalizer of claim 3, wherein a grazing angle between the moveable mirror layer and the first signal copy reflected by the moveable mirror layer comprises an angle that is less than forty-five degrees.
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14. The gain equalizer device of claim 3, further comprising a second MEMS device disposed between the first MEMS device and the output port, the second MEMS device comprising a moveable mirror layer operable to receive a phase shifted first signal copy from the first MEMS device and to change its position relative to the first MEMS device to introduce a further phase shift to the first signal copy.
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15. The gain equalizer of claim 3, further comprising at least one additional reflective surface between the beam splitter and the first MEMS device.
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16. The gain equalizer of claim 3, further comprising a bypass path coupled between the wavelength division demultiplexer and the wavelength division multiplexer, the bypass path operable to communicate at least one wavelength directly between the demultiplexer and the multiplexer without adjusting the gain of the at least one wavelength.
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17. The gain equalizer of claim 3, wherein the beam splitter is a partially silvered mirror, a mirror having one or more layers of a dielectric coating, or a fiber coupler.
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18. A method of facilitating gain equalization of a plurality of wavelengths, the method comprising:
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receiving an optical input signal comprising a plurality of wavelengths;
separating the optical signal into a plurality of wavelength signals;
communicating at least some of the wavelength signals to an array of attenuators;
at each attenuator;
communicating a first copy of the input wavelength signal toward a first reflective surface and a second copy of the input wavelength signal toward a second reflective surface, at least one of the reflective surfaces comprising a moveable mirror layer of a first micro-electro-optic system (MEMS) device;
reflecting the first and second wavelength signal copies toward an output;
combining components of the reflected first and second wavelength signal copies to form at least one output wavelength signal, wherein the first copy of the input wavelength signal and the second copy of the input wavelength signal comprise unequal amplitudes; and
displacing the moveable mirror layer in a substantially piston-like motion to result in an interference between the first and second wavelength signal copies at the output and a corresponding change in the amplitude of the output wavelength signal relative to the amplitude of the input wavelength signal. - View Dependent Claims (19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30)
wherein changing the position of the moveable mirror layer comprises displacing the moveable mirror layer relative to the inner conductive layer in response to a voltage difference between the moveable mirror layer and the inner conductive layer.
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22. The method of claim 21, wherein the moveable mirror layer comprises a plurality of adjacent mirror strips, at least some of the plurality of adjacent mirror strips separated by air gaps operable to relieve air damping when the mirror strips move relative to the inner conductive layer.
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23. The method of claim 22, wherein changing the position of the moveable mirror layer comprises displacing all of the moveable mirror strips relative to the inner conductive layer substantially in unison in response to the voltage difference.
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24. The method of claim 22, wherein changing the position of the moveable mirror layer comprises:
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coupling either the inner conductive layer or each of the moveable mirror strips to a ground; and
applying to the other a control voltage signal.
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25. The method of claim 21, wherein changing the position of the moveable mirror layer comprises selectively displacing the moveable mirror layer relative to the inner conductive layer, wherein the distance increases as the voltage difference between the moveable mirror layer and the inner conductive layer increases.
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26. The method of claim 18;
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the first reflective surface comprises the moveable mirror layer of the first MEMS device; and
the second reflective surface comprises a moveable mirror layer of a second MEMS device.
- wherein;
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27. The method of claim 26, further comprising changing the position of the moveable mirror layer of the second MEMS device to result in additional interference between the first and second signal copies at the output and a corresponding change in the amplitude of the output wavelength signal relative to the amplitude of the input wavelength signal.
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28. The method of claim 18, further comprising positioning the first and second reflective surfaces at an angle of less than forty-five degrees to the first and second wavelength signal copies, respectively.
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29. The method of claim 18, further comprising:
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receiving at a third reflective surface and a fourth reflective surface, the reflected first and second wavelength signal copies from the first and second reflective surfaces, respectively;
further reflecting the reflected first and second wavelength signal copies toward the output; and
changing the position of the third reflective surface to result in a further interference between the first and second wavelength signal copies at the output and a corresponding change in the amplitude of the output signal relative to the amplitude of the input wavelength signal.
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30. The method of claim 18, further comprising communicating at least one of the wavelength signals over a communication link bypassing the array of phase shift stages.
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31. A gain equalizer, comprising:
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a wavelength division demultiplexer operable to separate one or more communication bands into a plurality of wavelengths;
an array of phase shifter stages each comprising;
a micro-electro-optic system (MEMS) device comprising a moveable mirror layer including a plurality of adjacent mirror strips operable to receive a first copy of an input signal from a beam splitter and to reflect the first copy of the input signal for combination with a second copy of the input signal at an output port to form an output signal, the mirror strips displaceable substantially in unison in a substantially piston-like motion to introduce a phase shift between the first and second signal copies at the output port, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer, wherein the first copy, wherein the first copy of the input signal and the second copy of the input signal comprise unequal amplitudes; and
a wavelength division multiplexer operable to receive a plurality of phase shifted wavelengths and to multiplex at least some of the phase shifted wavelengths into an optical output signal.
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32. A method of facilitating gain equalization of a plurality of wavelengths, the method comprising:
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receiving an optical input signal comprising a plurality of wavelengths;
separating the optical signal into a plurality of wavelength signals;
communicating at least some of the wavelength signals to an array of attenuators;
at each attenuator;
communicating a first copy of the input wavelength signal toward a first reflective surface and a second copy of the input wavelength signal toward a second reflective surface, at least one of the reflective surfaces comprising a moveable mirror layer of a first micro-electro-optic system (MEMS) device, the moveable mirror layer comprising a plurality of adjacent strips operable to receive one of the first or second signal copies;
reflecting the first and second wavelength signal copies toward an output;
combining components of the reflected first and second wavelength signal copies to form at least one output wavelength signal, wherein the first copy of the input wavelength signal and the second copy of the input wavelength signal comprise unequal amplitudes; and
displacing the mirror strips substantially in unison in a substantially piston-like motion to result in an interference between the first and second wavelength signal copies at the output and a corresponding change in the amplitude of the output wavelength signal relative to the amplitude of the input wavelength signal.
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33. A gain equalizer, comprising:
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a wavelength division demultiplexer operable to separate one or more communication bands into a plurality of wavelengths;
an array of devices each comprising;
a first micro-electro-optic system (MEMS) device comprising a moveable mirror layer operable to receive a first copy of an input signal from a first beam splitter and to reflect the first copy of the input signal for combination with a second copy of the input signal at an output port to form an output signal, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer, wherein the first copy of the input signal and the second copy of the input signal comprise unequal amplitudes; and
a wavelength division multiplexer operable to receive a plurality of output signal wavelengths and to multiplex at least some of the output signal wavelengths into an optical output signal.
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34. A method of facilitating gain equalization of a plurality of wavelengths, the method comprising:
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receiving an optical input signal comprising a plurality of wavelengths;
separating the optical signal into a plurality of wavelength signals;
communicating at least some of the wavelength signals to an array of attenuators;
at each attenuator;
communicating a first copy of the input wavelength signal toward a reflective surface, the reflective surface comprising a moveable mirror layer of a first micro-electro-optic system (MEMS) device;
reflecting the first wavelength signal copy and a second wavelength signal copy toward an output;
combining components of the reflected first and second wavelength signal copies to form at least one output wavelength signal, wherein the first copy of the input wavelength signal and the second copy of the input wavelength signal comprise unequal amplitudes; and
displacing the moveable mirror layer to cause a change in the amplitude of the output wavelength signal relative to the amplitude of the input wavelength signal.
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35. A multiple band optical communication system, comprising:
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a plurality of optical amplifiers, each operable to receive and amplify at least one of a plurality of communication bands, each communication band comprising a plurality of wavelengths; and
a gain equalizer coupled to at least one of the plurality of optical amplifiers, the gain equalizer operable to receive one of the plurality of amplified wavelengths and to selectively introduce attenuation or gain into each wavelength;
wherein the gain equalizer comprises;
a wavelength division demultiplexer operable to separate one or more communication bands into a plurality of wavelengths;
an array of devices each comprising;
a micro-electro-optic system (MEMS) device comprising a moveable mirror layer operable to receive a first copy of an input signal from a beam splitter and to reflect the first copy of the input signal for combination with a second copy of the input signal at an output to form an output signal, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer, wherein the first copy of the input signal and the second copy of the input signal comprise unequal amplitudes; and
a wavelength division multiplexer operable to receive a plurality of output signal wavelengths and to multiplex at least some of the output signal wavelengths into an optical output signal.
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36. A gain equalizer, comprising:
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a wavelength division demultiplexer operable to separate one or more communication bands into a plurality of wavelengths;
an array of phase shifter stages each comprising;
a micro-electro-optic system (MEMS) device comprising a moveable mirror layer including a plurality of adjacent mirror strips operable to receive a first copy of an input signal from a beam splitter and to reflect the first copy of the input signal for combination with a second copy of the input signal at an output port to form an output signal, the amplitude of the output signal varying depending on the displacement of the moveable mirror layer, wherein the first copy of the input signal and the second copy of the input signal comprise unequal amplitudes; and
a wavelength division multiplexer operable to receive a plurality of output signal wavelengths and to multiplex at least some of the output signal wavelengths into an optical output signal.
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Specification
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Current AssigneeCheetah Omni LLC
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Original AssigneeCheetah Omni LLC
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InventorsIslam, Mohammed N., Kuditcher, Amos
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Primary Examiner(s)Bovernick, Rodney
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Assistant Examiner(s)Kang, Juliana K.
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Application NumberUS09/746,813Time in Patent Office1,208 DaysField of Search385/18, 385/19, 385/24, 385/25, 385/31, 385/33, 385/47, 359/109, 359/196, 359/212, 359/223, 359/333, 359/337.1US Class Current385/24CPC Class CodesG02B 6/3516 the reflective optical elem...G02B 6/356 in an optical cross-connect...G02B 6/357 Electrostatic force electro...G02B 6/3594 Characterised by additional...H04B 10/25073 using spectral equalisation...H04J 14/0221 Power control, e.g. to keep...
