Fault-tolerant fiber-optical beam control modules
First Claim
1. An optical micromechanical system for controlling reflectivity of a single light beam from an optical source, the optical micromechanical system includinga macropixel comprising a plurality of individual micromirrors which are closely spaced with respect to the wavelength of the light beam and arranged such that the light beam impinges substantially concurrently on the plurality of micromirrors, each of the micromirrors being electronically controllable to effect a mechanical movement, the macropixel being operable in a first mode for concurrently maintaining an alignment of the micromirrors at a common displacement for maximizing reflection of the single light beam in a selected path, and the macropixel being operable in a second mode for aligning some of the micromirrors in into a different displacement for deflecting portions of the light beam impinging on the aligned micromirrors out of the selected path so as to effectively attenuate the reflected light beam.
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Accused Products
Abstract
Fiber-optic beam routing and amplitude control modules based on a unique fault-tolerant scheme using a macro-pixel to control an optical beam are proposed. The unique macro-pixel method involving multiple device pixels per beam inherently provides a robust digital technique for module control while adding to the optical beam alignment tolerance and resistance to catastropic failure for the overall module. The macropixel approach solves the speed versus alignment and failure sensitivity dilemma present in single pixel element based optical micromechanical systems (MEMS). Specifically proposed are fault tolerant fiber-optic attenuators and switches using several microactuated micromirrors per optical beam. Transmissive and reflective module geometries are proposed using small tilt and small distance piston-action micromirrors, leading to fast module reconfiguration speed fiber optic signal controls. The macro-pixel design approach is extended to other pixel technologies such as polarization rotating pixels. The proposed fiber-optic attenuator and switch designs can be extended to realize a complex network of multiple attenuators and switches that can be applied to N-wavelength multiplexed fiber-optic networks.
13 Citations
21 Claims
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1. An optical micromechanical system for controlling reflectivity of a single light beam from an optical source, the optical micromechanical system including
a macropixel comprising a plurality of individual micromirrors which are closely spaced with respect to the wavelength of the light beam and arranged such that the light beam impinges substantially concurrently on the plurality of micromirrors, each of the micromirrors being electronically controllable to effect a mechanical movement, the macropixel being operable in a first mode for concurrently maintaining an alignment of the micromirrors at a common displacement for maximizing reflection of the single light beam in a selected path, and the macropixel being operable in a second mode for aligning some of the micromirrors in into a different displacement for deflecting portions of the light beam impinging on the aligned micromirrors out of the selected path so as to effectively attenuate the reflected light beam.
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13. An optical mechanical system for controlling reflectivity of a light beam from an optical source, the system including
a plurality of macropixels, each macropixel comprising a plurality of individual micromirrors which are closely spaced with respect to the wavelength of the light beam, each of the micromirrors being electronically controllable to effect a mechanical movement, the macropixel being operable in a first mode for concurrently maintaining an alignment of the micromirrors at a common displacement for maximizing reflection of the light beam in a selected path, the macropixel being operable in a second mode for aligning some of the micromirrors in a different displacement so as to effectively attenuate the reflected light beam; - wherein the displacement of the micromirrors comprises an angular tilt of each micromirror;
wherein the plurality of macropixels are aligned in a 2-dimensional array, a cube beam splitter positioned in a light beam path with one face thereof adjacent said array, a fixed mirror positioned adjacent a second face of said beam splitter, a first plurality of input light lenses positioned for bi-directional transfer of light beams to said beam splitter at a third face of said beam splitter and a second plurality of output light lenses positioned for bi-directional transfer of light to said beam splitter at a fourth face thereof, the beam splitter being effective to split a light beam impinging thereon into two equal beam components, one of said beam components traveling through said beam splitter to said macropixel array and the other of said beam components being directed onto said fixed mirror, each of said beam components being reflected back into said beam splitter to create an interference along a diagonal of said beam splitter such that when an optical path difference between the two beam components is equal to a multiple of the optical beam wavelength, the beam from one of the input and output lenses is transferred to the other of the input and output buses, and, when the optical path difference is equal to one-half of an optical beam wavelength, the beam is directed back to its source lens, the optical beam path length through the beam splitter being adjustable by linear movement of each macropixel. - View Dependent Claims (14)
- wherein the displacement of the micromirrors comprises an angular tilt of each micromirror;
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15. An optical micromechanical system for controlling reflectivity of a light beam from an optical source, the system including
a plurality of macropixels, each macropixel comprising a plurality of individual micromirrors which are closely spaced with respect to the wavelength of the light beam, each of the micromirrors being electronically controllable to effect a mechanical movement, the macropixel being operable in a first mode for concurrently maintaining an alignment of the micromirrors at a common displacement for maximizing reflection of the light beam in a selected path, the macropixel being operable in a second mode for aligning some of the micromirrors in a different displacement so as to effectively attenuate the reflected light beam; - and
a multiplexor/demultiplexor for providing a plurality of light beams, each of the plurality of beams being directed onto a respective one of the plurality of macropixels, and each of the plurality of macropixels being controllable to attenuate reflected light intensity.
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16. A 2×
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2 optical switch, the switch including
a first macropixel and a second macropixel, each macropixel comprising a plurality of individual micromirrors which are closely spaced with respect to the wavelength of the light beam, each of the micromirrors being electronically controllable to effect a mechanical movement, the macropixel being operable in a first mode for concurrently maintaining an alignment of the micromirrors at a common displacement for maximizing reflection of the light beam in a selected path, the macropixel being operable in a second mode for aligning some of the micromirrors in a different displacement so as to effectively attenuate the reflected light beam;
first and second input ports, first and second output ports, wherein the first macropixel has a first orientation for reflecting light from said first input port to said first output port, and wherein the second macropixel has a first orientation for reflecting light from said second input port to said second output port, and first and second fixed mirrors positioned adjacent and facing toward a respective one of said macropixels, each of said macropixels being controllable by angularly tilting the micromirrors thereof for reflecting light onto respective ones of said fixed mirrors, said fixed mirrors reflecting light from each macropixel to the other of the macropixels whereby light from the first and second input ports is reflected to the second and first output ports, respectively.
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2 optical switch, the switch including
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17. A multi-wavelength 2×
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2 optical switch, the switch including
a plurality of macropixels comprising a plurality of individual micromirrors which are closely spaced with respect to the wavelength of the light beam, each of the micromirrors being electronically controllable to effect a mechanical movement, each macropixel being operable in a first mode for concurrently maintaining an alignment of the micromirrors at a common displacement for maximizing reflection of the light beam in a selected path, each macropixel being operable in a second mode for aligning some of the micromirrors in a different displacement so as to effectively attenuate the reflected light beam;
wherein the plurality of macropixels are arranged in a linear array, a first optical multiplexor/demultiplexer device for directing respective light beam wavelengths onto corresponding ones of the macropixels and for receiving reflected light therefrom, and a second optical multiplexor/demultiplexor device for directing respective light beam wavelengths onto corresponding ones of the macropixels and for receiving reflected light therefrom, a fixed mirror, said plurality of macropixels being separately controllable so as to be aligned in a first orientation for reflecting light from said first optical device back to said first optical device and for reflecting light from said second optical device onto said fixed mirror, back to said plurality of macropixels and to said second optical device, said plurality of macropixels being alignable in another orientation for reflecting light from one of said first and second optical devices to the other of said first and second optical devices.
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2 optical switch, the switch including
Specification