Patents by Inventor Robert M. Boysel
Robert M. Boysel has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 8077372Abstract: A microshutter array has a frame having a light transmissive portion. Linear microshutter elements extend across the light transmissive portion and in parallel to each other. Each microshutter element has a flat blade extended in a length direction and first and second torsion arms extending outwards from each side of the blade in the length direction, the blade extending across the light transmissive portion. There is at least one electrode associated with each linear microshutter element and extended in the length direction parallel to the microshutter element.Type: GrantFiled: January 21, 2010Date of Patent: December 13, 2011Assignee: OmniVision Technologies, Inc.Inventors: John N. Border, Herbert J. Erhardt, J. Kelly Lee, Marek W. Kowarz, Robert M. Boysel
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Publication number: 20100118176Abstract: A microshutter array has a frame having a light transmissive portion. Linear microshutter elements extend across the light transmissive portion and in parallel to each other. Each microshutter element has a flat blade extended in a length direction and first and second torsion arms extending outwards from each side of the blade in the length direction, the blade extending across the light transmissive portion. There is at least one electrode associated with each linear microshutter element and extended in the length direction parallel to the microshutter element.Type: ApplicationFiled: January 21, 2010Publication date: May 13, 2010Inventors: John N. Border, Herbert J. Erhardt, J. Kelly Lee, Marek W. Kowarz, Robert M. Boysel
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Patent number: 7684101Abstract: A microshutter array has a frame having a light transmissive portion. Linear microshutter elements extend across the light transmissive portion and in parallel to each other. Each microshutter element has a flat blade extended in a length direction and first and second torsion arms extending outwards from each side of the blade in the length direction, the blade extending across the light transmissive portion. There is at least one electrode associated with each linear microshutter element and extended in the length direction parallel to the microshutter element.Type: GrantFiled: October 11, 2007Date of Patent: March 23, 2010Assignee: Eastman Kodak CompanyInventors: John N. Border, Herbert J. Erhardt, J. Kelly Lee, Marek W. Kowarz, Robert M. Boysel
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Patent number: 5774252Abstract: A membrane device is provided in which a plurality of ridges (14) and recesses (16) are formed proximate to a substrate (12). Electrodes (18) are formed within the recesses (16). A spacer (20) supports a membrane (22). Application of a potential difference between the membrane (22) and the electrodes (18) allows for deflection of the membrane (22) toward the electrodes (18).Type: GrantFiled: April 19, 1996Date of Patent: June 30, 1998Assignee: Texas Instruments IncorporatedInventors: Tsen-Hwang Lin, Gregory A. Magel, Wen R. Wu, Robert M. Boysel
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Patent number: 5721801Abstract: A method of manufacturing an optical waveguide device. The method involves removing a portion of an upper cladding layer 110 from above a waveguide 106 and depositing a temporary spacer layer 114 in place of the removed upper cladding 110. A metal membrane 116 is deposited and patterned over the temporary spacer layer 114 and the temporary spacer 114 is removed, leaving the metal membrane 116 suspended over the waveguide 106. When a voltage differential is applied between the metal membrane 116 and electrodes 108 formed on a lower cladding 102, the metal membrane 116 is collapsed against the waveguide 106, attenuating any light transmitted by the waveguide 106.Type: GrantFiled: December 17, 1996Date of Patent: February 24, 1998Assignee: Texas Instruments IncorporatedInventor: Robert M. Boysel
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Patent number: 5703728Abstract: A support pillar 426 for use with a micromechanical device, particularly a digital micromirror device, comprising a pillar material 422 supported by a substrate 400 and covered with a metal layer 406. The support pillar 426 is fabricated by depositing a layer of pillar material on a substrate 400, patterning the pillar layer to define a support pillar 426, and depositing a metal layer 406 over the support pillar 426 enclosing the support pillar. A planar surface even with the top of the pillar may be created by applying a spacer layer 432 over the pillars 426. After applying the spacer layer 432, the spacer layer 432 is etched to expose the tops of the pillars.Type: GrantFiled: November 2, 1994Date of Patent: December 30, 1997Assignee: Texas Instruments IncorporatedInventors: Gregory C. Smith, Robert M. Boysel
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Patent number: 5701372Abstract: The present invention provides a method and a circuit architecture whereby a time delay for optical signals in an integrated optical circuit is implemented in a hybrid configuration. For example, a hybrid time delay circuit could be implemented with a three chip set composed of a switch chip 34 placed between two delay chips 36,38. The delay chips may include one or more delay loops 44 and preferably an associated bypass loop for each delay loop 42. The switch chip contains an optical switch 20 for each delay loop on the delay chips and may contain switch control circuitry or an interface to external switch control circuitry.Type: GrantFiled: October 22, 1996Date of Patent: December 23, 1997Assignee: Texas Instruments IncorporatedInventors: Gregory A. Magel, Robert M. Boysel
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Patent number: 5631782Abstract: Support pillar 426 for use with a micromechanical device, particularly a digital micromirror device, comprising a pillar material 422 supported by a substrate 400 and covered with a metal layer 406. The support pillar 426 is fabricated by depositing a layer of pillar material on a substrate 400, patterning the pillar layer to define a support pillar 426, and depositing a metal layer 406 over the support pillar 426 enclosing the support pillar. A planar surface even with the top of the pillar may be created by applying a spacer layer 432 over the pillars 426. After applying the spacer layer 432, the spacer layer 432 is etched to expose the tops of the pillars.Type: GrantFiled: June 7, 1995Date of Patent: May 20, 1997Assignee: Texas Instruments IncorporatedInventors: Gregory C. Smith, Robert M. Boysel
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Patent number: 5629794Abstract: A spatial light modulator (40, 70, 80) operable in the analog mode for light beam steering or scanning applications. A deflectable mirror (42, 72) is supported by a torsion hinge (44) along a torsion axis. A plurality of flexure hinges (48) are provided to support the corners of the mirror (42, 72) and provide a restoration force. The combination of the torsion hinges and the flexure hinges realizes a deflectable pixel that is operable in the linear range for a large range of address voltages. The flexure hinges also maintain a flat undeflected state when no address voltage is applied, and prevent the pixel from collapsing. The pixel may be reinforced, such as about its perimeter (74) to ensure mirror flatness and prevent warping, even during extreme deflections of the mirror. The pixel is electrostatically deflected by applying an address voltage to an underlying address electrode (60).Type: GrantFiled: May 31, 1995Date of Patent: May 13, 1997Assignee: Texas Instruments IncorporatedInventors: Gregory A. Magel, James M. Florence, Robert M. Boysel
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Patent number: 5618759Abstract: A method of immobilizing both (i) a semiconductor wafer (16) during the sawing thereof to form individual chips (18) and (ii) the resulting chips (18) as and after sawing of the wafer (16) is completed. A negative pressure is applied to the wafer (16) through a wafer carrier (12) to immobilize the wafer and individual chips. The negative pressure is applied to the wafer via ports (30) in alignment with the location of each chip (18) to be formed. A grid (40) or negative pressure is used to restrain the chips as they are subsequently transported following sawing.Type: GrantFiled: May 31, 1995Date of Patent: April 8, 1997Assignee: Texas Instruments IncorporatedInventor: Robert M. Boysel
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Patent number: 5551293Abstract: An accelerative force may be measured using a plurality of deflection elements (102), each deflection element (102) comprising an inertial mass (104), and at least one hinge (104) supporting the inertial mass (104) in a normal position. Application of a force to inertial mass (104) will result in the deflection of the inertial mass (104) in a first direction out of the normal position. The movement of the inertial mass (104) from the normal position stores energy in the hinges (108) which tends to move the inertial mass (104) in a second direction back to its normal position. Either the mass of the inertial mass (104), or the compliance of the hinges (108) is varied from one deflection element (102) in the array to another so that the force applied to the inertial masses (104) by simultaneous acceleration of the deflection elements (102) deflects some of the inertial masses (104). A detection means (112) senses if inertial masses (104) have deflected and produces an output representative of the applied force.Type: GrantFiled: June 7, 1995Date of Patent: September 3, 1996Assignee: Texas Instruments IncorporatedInventors: Robert M. Boysel, Jeffrey B. Sampsell
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Patent number: 5526688Abstract: An accelerative force may be measured using a plurality of deflection elements (102), each deflection element (102) comprising an inertial mass (104), and at least one hinge (104) supporting the inertial mass (104) in a normal position. Application of a force to inertial mass (104) will result in the deflection of the inertial mass (104) in a first direction out of the normal position. The movement of the inertial mass (104) from the normal position stores energy in the hinges (108) which tends to move the inertial mass (104) in a second direction back to its normal position. Either the mass of the inertial mass (104), or the compliance of the hinges (108) is varied from one deflection element (102) in the array to another so that the force applied to the inertial masses (104) by simultaneous acceleration of the deflection elements (102) deflects some of the inertial masses (104). A detection means (112) senses if inertial masses (104) have deflected and produces an output representative of the applied force.Type: GrantFiled: April 26, 1994Date of Patent: June 18, 1996Assignee: Texas Instruments IncorporatedInventors: Robert M. Boysel, Jeffrey B. Sampsell
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Patent number: 5305640Abstract: Acceleration is measured using an array of micro-machined elements. The array is configured so each successive element is deflected by a higher acceleration. For each acceleration there will be a set of elements that is deflected. By determining the transition point between deflected and undeflected elements, the acceleration can be measured.Type: GrantFiled: May 1, 1992Date of Patent: April 26, 1994Assignee: Texas Instruments IncorporatedInventors: Robert M. Boysel, Jeffrey B. Sampsell
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Patent number: 5278925Abstract: It is possible to utilize changes in the complex effective refractive index caused by bringing a metal membrane in close proximity to the core of an optical waveguide to form many devices. The invention described herein provides structures and processes that do so, the structure comprising a substrate, a lower cladding, a waveguide core, a removable upper cladding which supports a metal membrane, and an electrode for deflecting said membrane.Switchable devices using this structure include, but are not limited to, polarizers, mode converters, optical switches, Bragg devices, directional couplers and channel waveguides.Type: GrantFiled: April 13, 1993Date of Patent: January 11, 1994Assignee: Texas Instruments IncorporatedInventors: Robert M. Boysel, Gregory A. Magel
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Patent number: 5192395Abstract: It is possible to determine acceleration using an array of micro-machined elements. The invention described herein details how to do so by fabricating an array of structures with a substrate, addressing circuitry, a spacer layer forming a well over the addressing circuitry, and a deflection element over the well. The deflection elements are configured so each element is deflected by a higher acceleration. The invention also shows one embodiment of the invention.Type: GrantFiled: October 12, 1990Date of Patent: March 9, 1993Assignee: Texas Instruments IncorporatedInventors: Robert M. Boysel, Jeffrey B. Sampsell
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Patent number: 5178728Abstract: It is possible to utilize changes in the complex effective refractive index caused by bringing a metal membrane in close proximity to the core of an optical waveguide to form many devices. The invention described herein provides structures and processes that do so, the structure comprising a substrate, a lower cladding, a waveguide core, a removable upper cladding which supports a metal membrane, and an electrode for deflecting said membrane.Switchable devices using this structure include, but are not limited to, polarizers, mode converters, optical switches, Bragg devices, directional couplers and channel waveguides.Type: GrantFiled: March 28, 1991Date of Patent: January 12, 1993Assignee: Texas Instruments IncorporatedInventors: Robert M. Boysel, Gregory A. Magel