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| 20090304327 | METHOD AND APPARATUS FOR IMPLEMENTING OPTICAL DEFLECTION SWITCHING USING COUPLED RESONATORS - A method of implementing optical deflection switching includes directing a tuning operation at a specific region of coupled optical resonators coupled to an input port, a first output port and a second output port, the coupled optical resonator including a plurality of cascaded unit cells; wherein the tuning operation interrupts a resonant coupling between one or more of the unit cells of the coupled resonators so as to cause an input optical signal from the input port to be directed from the first output port to the second output port. | 12-10-2009 |
| 20090324162 | CMOS COMPATIBLE INTEGRATED DIELECTRIC OPTICAL WAVEGUIDE COUPLER AND FABRICATION - An optoelectronic circuit fabrication method and integrated circuit apparatus fabricated therewith. Integrated circuits are fabricated with an integral optical coupling transition to efficiently couple optical energy from an optical fiber to an integrated optical waveguide on the integrated circuit. Layers of specific materials are deposited onto a semiconductor circuit to support etching of a trench to receive an optical coupler that performs proper impedance matching between an optical fiber and an on-circuit optical waveguide that extends part way into the transition channel. A silicon based dielectric that includes at least a portion with a refractive index substantially equal to a section of the optical fiber is deposited into the etched trench to create the optical coupler. Silicon based dielectrics with graded indices are also able to be used. Chemical mechanical polishing is used finalize preparation of the optical transition and integrated circuit. | 12-31-2009 |
| 20100111470 | LOW-LOSS LOW-CROSSTALK INTEGRATED DIGITAL OPTICAL SWITCH - An optical switch includes a plurality of optical interferometric structures is serially connected between at least one optical input node and two optical output nodes. A primary waveguide directly connects an optical input node and a first optical output node. A complementary waveguide, which is directly connected to a second optical output node, is evanescently coupled with the primary waveguide in a pair of optically coupled sections provided in each optical interferometric structure. Each optical interferometric structure also includes a pair of decoupled sections, which includes a primary decoupled section embedding a portion of the primary waveguide and a complementary decoupled section which includes a portion of the complementary waveguide. The complementary decoupled section is embedded in a phase tuning structure that allows modulation of the phase of the optical signal passing through. The optical switch provides less insertion loss, less crosstalk, and wider bandwidth than prior art optical switches. | 05-06-2010 |
| 20130330036 | EXCITING A SELECTED MODE IN AN OPTICAL WAVEGUIDE - A method of exciting a selected light propagation mode in a device is disclosed. At least two light beams are propagated proximate a waveguide of the device substantially parallel to a selected surface of the waveguide. Light is transferred from the at least two beams of light into the waveguide through the selected surface to excite the selected light propagation mode in the waveguide. | 12-12-2013 |
| 20130330037 | EXCITING A SELECTED MODE IN AN OPTICAL WAVEGUIDE - A method of exciting a selected light propagation mode in a device is disclosed. At least two light beams are propagated proximate a waveguide of the device substantially parallel to a selected surface of the waveguide. Light is transferred from the at least two beams of light into the waveguide through the selected surface to excite the selected light propagation mode in the waveguide. | 12-12-2013 |
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| 20090290831 | Junction Field Effect Transistor Geometry for Optical Modulators - An optoelectronic apparatus for controlling a signal includes an optical waveguide having a variable refractive index; an active device formed within the waveguide, the device having three electrodes, a drain, a source and a gate; and wherein the device is located within the waveguide so that current flowing from the drain to the source changes the refractive index. | 11-26-2009 |
| 20110007761 | TEMPERATURE CONTROL DEVICE FOR OPTOELECTRONIC DEVICES - Current may be passed through an n-doped semiconductor region, a recessed metal semiconductor alloy portion, and a p-doped semiconductor region so that the diffusion of majority charge carriers in the doped semiconductor regions transfers heat from or into the semiconductor waveguide through Peltier-Seebeck effect. Further, a temperature control device may be configured to include a metal semiconductor alloy region located in proximity to an optoelectronic device, a first semiconductor region having a p-type doping, and a second semiconductor region having an n-type doping. The temperature of the optoelectronic device may thus be controlled to stabilize the performance of the optoelectronic device. | 01-13-2011 |
| 20110024608 | AVALANCHE IMPACT IONIZATION AMPLIFICATION DEVICES - A semiconductor photodetector may provide charge carrier avalanche multiplication at high field regions of a semiconductor material layer. A semiconductor current amplifier may provide current amplification by impact ionization near a high field region. A plurality of metal electrodes are formed on a surface of a semiconductor material layer and electrically biased to produce a non-uniform high electric field in which the high electric field strength accelerates avalanche electron-hole pair generation, which is employed as an effective avalanche multiplication photodetection mechanism or as an avalanche impact ionization current amplification mechanism. | 02-03-2011 |
| 20110052200 | MULTI-MODE MULTIPLEXING USING STAGED COUPLING AND QUASI-PHASE-MATCHING - A mode-selective add/drop unit for a mode division de/multiplexing device includes an optical ADU waveguide adapted for coupling to an input optical waveguide. The optical ADU waveguide includes at least one region providing optical signal coupling between the ADU waveguide and a multi-mode waveguide; and, one or more phase matching regions for controlling a relative or absolute phase difference between an electromagnetic wave (EMW) carried in the ADU waveguide and the multi-mode waveguide. The mode-selective add/drop unit may further include a transition region connecting the coupling region and a phase matching region, wherein a shape of a transition region is governed by a polynomial function, exponential function, logarithmic function, trigonometric function or, any combination of these functions. | 03-03-2011 |
| 20120330625 | MULTI-MODE MULTIPLEXING USING STAGED COUPLING AND QUASI-PHASE-MATCHING - A mode-selective add/drop unit for a mode division de/multiplexing device includes an optical ADU waveguide adapted for coupling to an input optical waveguide. The optical ADU waveguide includes at least one region providing optical signal coupling between the ADU waveguide and a multi-mode waveguide; and, one or more phase matching regions for controlling a relative or absolute phase difference between an electromagnetic wave (EMW) carried in the ADU waveguide and the multi-mode waveguide. The mode-selective add/drop unit may further include a transition region connecting the coupling region and a phase matching region, wherein a shape of a transition region is governed by a polynomial function, exponential function, logarithmic function, trigonometric function or, any combination of these functions. | 12-27-2012 |
| 20130137202 | TEMPERATURE CONTROL DEVICE FOR OPTOELECTRONIC DEVICES - Current may be passed through an n-doped semiconductor region, a recessed metal semiconductor alloy portion, and a p-doped semiconductor region so that the diffusion of majority charge carriers in the doped semiconductor regions transfers heat from or into the semiconductor waveguide through Peltier-Seebeck effect. Further, a temperature control device may be configured to include a metal semiconductor alloy region located in proximity to an optoelectronic device, a first semiconductor region having a p-type doping, and a second semiconductor region having an n-type doping. The temperature of the optoelectronic device may thus be controlled to stabilize the performance of the optoelectronic device. | 05-30-2013 |
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| 20110143482 | SUSPENDED GERMANIUM PHOTODETECTOR FOR SILICON WAVEGUIDE - A vertical stack of a first silicon germanium alloy layer, a second epitaxial silicon layer, a second silicon germanium layer, and a germanium layer are formed epitaxially on a top surface of a first epitaxial silicon layer. The second epitaxial silicon layer, the second silicon germanium layer, and the germanium layer are patterned and encapsulated by a dielectric cap portion, a dielectric spacer, and the first silicon germanium layer. The silicon germanium layer is removed between the first and second silicon layers to form a silicon germanium mesa structure that structurally support an overhanging structure comprising a stack of a silicon portion, a silicon germanium alloy portion, a germanium photodetector, and a dielectric cap portion. The germanium photodetector is suspended by the silicon germanium mesa structure and does not abut a silicon waveguide. Germanium diffusion into the silicon waveguide and defect density in the germanium detector are minimized. | 06-16-2011 |
| 20140127878 | FABRICATION OF LOCALIZED SOI ON LOCALIZED THICK BOX USING SELECTIVE EPITAXY ON BULK SEMICONDUCTOR SUBSTRATES FOR PHOTONICS DEVICE INTEGRATION - Photonic devices are created by laterally growing a semiconductor material (i.e., a localized semiconductor-on-insulator layer) over a localized buried oxide (BOX) created in a semiconductor by either a trench isolation process or thermal oxidation. In one embodiment, and after trench formation in a semiconductor substrate, the trench is filled with oxide to create a localized BOX. The top surface of the BOX is recessed to depth below the topmost surface of the semiconductor substrate to expose sidewall surfaces of the semiconductor substrate within each trench. A semiconductor material is then epitaxially grown from the exposed sidewall surfaces of the semiconductor substrate. | 05-08-2014 |
| 20150348827 | FABRICATION OF LOCALIZED SOI ON LOCALIZED THICK BOX USING SELECTIVE EPITAXY ON BULK SEMICONDUCTOR SUBSTRATES FOR PHOTONICS DEVICE INTEGRATION - Photonic devices are created by laterally growing a semiconductor material (i.e., a localized semiconductor-on-insulator layer) over a localized buried oxide (BOX) created in a semiconductor by either a trench isolation process or thermal oxidation. In one embodiment, and after trench formation in a semiconductor substrate, the trench is filled with oxide to create a localized BOX. The top surface of the BOX is recessed to depth below the topmost surface of the semiconductor substrate to expose sidewall surfaces of the semiconductor substrate within each trench. A semiconductor material is then epitaxially grown from the exposed sidewall surfaces of the semiconductor substrate. | 12-03-2015 |
