Patents by Inventor James C. Baker
James C. Baker 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: 11932529Abstract: In described examples, a microelectromechanical system (MEMS) includes a first element and a second element. The first element is mounted on a substrate and has a first contact surface. The second element is mounted on the substrate and has a second contact surface that protrudes from the second element to form an acute contact surface. The first element and/or the second element is/are operable to move in: a first direction, such that the first contact surface comes in contact with the second contact surface; and a second direction, such that the second contact surface separates from the first contact surface.Type: GrantFiled: March 10, 2020Date of Patent: March 19, 2024Assignee: TEXAS INSTRUMENTS INCORPORATEDInventors: Patrick Ian Oden, James Carl Baker, Sandra Zheng, William C. McDonald
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Publication number: 20210290288Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a method of beginning an ablation procedure using a multi-electrode ablation system is described. The method includes selectively coupling the output of a power supply to a first electrode of a plurality of electrodes to increase a temperature at the first electrode to a first temperature set-point and limit a rate of increase of the temperature at the first electrode to a predetermined first rate.Type: ApplicationFiled: June 10, 2021Publication date: September 23, 2021Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Vincent Froehlich, Michael Olsen, Sukanya Varadharajan, Catherine A. Pipenhagen
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Patent number: 11058474Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a method of beginning an ablation procedure using a multi-electrode ablation system is described. The method includes selectively coupling the output of a power supply to a first electrode of a plurality of electrodes to increase a temperature at the first electrode to a first temperature set-point and limit a rate of increase of the temperature at the first electrode to a predetermined first rate.Type: GrantFiled: August 28, 2017Date of Patent: July 13, 2021Assignee: ST. JUDE MEDICAL, CARDIOLOGY DIVISION, INC.Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Vincent Froehlich, Michael Olsen, Sukanya Varadharajan, Catherine A. Pipenhagen
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Patent number: 10918434Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a multi-electrode ablation system includes a power supply configured to be coupled to a plurality of electrodes and a controller coupled to the power supply. The controller is configured to determine a thermal gain of each electrode of the plurality of electrodes. For each electrode of the plurality of electrodes, the controller sets a power limit based at least in part on said electrode's determined thermal gain. The power limit establishes a maximum power that may be dissipated through said electrode.Type: GrantFiled: May 3, 2018Date of Patent: February 16, 2021Assignee: ST. JUDE MEDICAL, CARDIOLOGY DIVISION, INC.Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Victor Froehlich, Michael Olsen, Sukanya Varadharajan
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Publication number: 20190011657Abstract: A mechanical fuse (100), (500) for an ADSS cable comprises a continuous length of ADSS cable, one or more anchors (15), (520), (530) for supporting the ADSS cable relative to a (pylon 7), and a knife, pin or the like (7), (630) which can kink, bend and/or cut the ADSS cable in a breaking region. When a load in excess of a predetermined amount is applied to the ADSS cable, for example when the ADSS cable is snagged by a vehicle, the mechanical (fuse 100), (500) breaks or separates causing the pin or knife ((7), 630) to facilitate breaking of the ADSS cable in the breaking region. A method of attaching an ADSS cable to a support (7) is also disclosed.Type: ApplicationFiled: December 23, 2016Publication date: January 10, 2019Inventors: James C. BAKER, Mark NAYLOR
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Publication number: 20180250059Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a multi-electrode ablation system includes a power supply configured to be coupled to a plurality of electrodes and a controller coupled to the power supply. The controller is configured to determine a thermal gain of each electrode of the plurality of electrodes. For each electrode of the plurality of electrodes, the controller sets a power limit based at least in part on said electrode's determined thermal gain. The power limit establishes a maximum power that may be dissipated through said electrode.Type: ApplicationFiled: May 3, 2018Publication date: September 6, 2018Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Victor Froehlich, Michael Olsen, Sukanya Varadharajan
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Patent number: 9987070Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a multi-electrode ablation system includes a power supply configured to be coupled to a plurality of electrodes and a controller coupled to the power supply. The controller is configured to determine a thermal gain of each electrode of the plurality of electrodes. For each electrode of the plurality of electrodes, the controller sets a power limit based at least in part on said electrode's determined thermal gain. The power limit establishes a maximum power that may be dissipated through said electrode.Type: GrantFiled: March 11, 2014Date of Patent: June 5, 2018Assignee: ST. JUDE MEDICAL, CARDIOLOGY DIVISION, INC.Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Victor Froehlich, Michael Olsen, Sukanya Varadharajan
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Patent number: 9864188Abstract: A method of forming a micro-electromechanical systems (MEMS) pixel, such as a DMD type pixel, by forming a substrate having a non-planar upper surface, and depositing a photoresist spacer layer upon the substrate. The spacer layer is exposed to a grey-scale lithographic mask to shape an upper surface of the spacer layer. A control member is formed upon the planarized spacer layer, and an image member is formed over the control member. The image member is configured to be positioned as a function of the control member to form a spatial light modulator (SLM). The spacer layer is planarized by masking a selected portion of the spacer layer with a grey-scale lithographic mask to remove binge in the selected portion.Type: GrantFiled: November 3, 2014Date of Patent: January 9, 2018Assignee: TEXAS INSTRUMENTS INCORPORATEDInventors: Patrick I. Oden, James C. Baker, Sandra Zheng, William C. McDonald, Lance W. Barron
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Publication number: 20170354454Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a method of beginning an ablation procedure using a multi-electrode ablation system is described. The method includes selectively coupling the output of a power supply to a first electrode of a plurality of electrodes to increase a temperature at the first electrode to a first temperature set-point and limit a rate of increase of the temperature at the first electrode to a predetermined first rate.Type: ApplicationFiled: August 28, 2017Publication date: December 14, 2017Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Vincent Froehlich, Michael Olsen, Sukanya Varadharajan, Catherine A. Pipenhagen
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Patent number: 9775663Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a method of beginning an ablation procedure using a multi-electrode ablation system is described. The method includes selectively coupling the output of a power supply to a first electrode of a plurality of electrodes to increase a temperature at the first electrode to a first temperature set-point and limit a rate of increase of the temperature at the first electrode to a predetermined first rate.Type: GrantFiled: March 11, 2014Date of Patent: October 3, 2017Assignee: St. Jude Medical, Cardiology Division, Inc.Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Vincent Froehlich, Michael Olsen, Sukanya Varadharajan, Catherine A. Pipenhagen
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Patent number: 9448484Abstract: A method of forming a micro-electromechanical systems (MEMS) pixel, such as a DMD-type pixel, by depositing a photoresist spacer layer upon a substrate. The photoresist spacer layer is exposed to a grey-scale lithographic mask to shape an upper surface of the photoresist spacer layer. A control member is formed upon the shaped spacer layer, and has a sloped portion configured to maximize energy density. An image member is configured to be positioned as a function of the control member to form a spatial light modulator (SLM).Type: GrantFiled: November 3, 2014Date of Patent: September 20, 2016Assignee: TEXAS INSTRUMENTS INCORPORATEDInventors: Patrick I. Oden, James C. Baker, Sandra Zheng, William C. McDonald, Lance W. Barron
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Publication number: 20160176701Abstract: A MEMs actuator device and method of forming includes arrays of actuator elements. Each actuator element has a moveable top plate and a bottom plate. The top plate includes a central membrane member and a cantilever spring for movement of the central membrane member. The bottom plate consists of two RF signal lines extending under the central membrane member. A MEMs electrostatic actuator device includes a CMOS wafer, a MEMs wafer, and a ball bond assembly. Interconnections are made from a ball bond to an associated through-silicon-via (TSV) that extends through the MEMS wafer. A RF signal path includes a ball bond electrically connected through a TSV and to a horizontal feed bar and from the first horizontal feed bar vertically into each column of the array. A metal bond ring extends between the CMOS wafer and the MEMS wafer. An RF grounding loop is completed from a ground shield overlying the array to the metal bond ring, a TSV and to a ball bond.Type: ApplicationFiled: February 15, 2016Publication date: June 23, 2016Inventors: Arun Gupta, William C. McDonald, Adam Fruehling, Ivan Kmecko, Lance Barron, Divyanshu Agrawal, Arthur M. Turner, John C. Ehmke, James C. Baker
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Patent number: 9340415Abstract: A MEMS device is formed with facing surfaces of a contoured substrate and a layer of material having complementary contours. In one fabrication approach, a first photoresist layer is formed over a substrate. Selected regions of the first photoresist layer are exposed using a patterning mask. The exposed regions of the first photoresist layer are thermally shrunk to pattern the first photoresist layer with a contour. A layer of material is formed over the contoured first photoresist layer.Type: GrantFiled: March 18, 2015Date of Patent: May 17, 2016Assignee: TEXAS INSTRUMENTS INCORPORATEDInventors: James C. Baker, Patrick I. Oden, Robert S. Black
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Publication number: 20160124302Abstract: A method of forming a micro-electromechanical systems (MEMS) pixel, such as a DMD type pixel, by forming a substrate having a non-planar upper surface, and depositing a photoresist spacer layer upon the substrate. The spacer layer is exposed to a grey-scale lithographic mask to shape an upper surface of the spacer layer. A control member is formed upon the planarized spacer layer, and an image member is formed over the control member. The image member is configured to be positioned as a function of the control member to form a spatial light modulator (SLM). The spacer layer is planarized by masking a selected portion of the spacer layer with a grey-scale lithographic mask to remove binge in the selected portion.Type: ApplicationFiled: November 3, 2014Publication date: May 5, 2016Inventors: Patrick I. Oden, James C. Baker, Sandra Zheng, William C. McDonald, Lance W. Barron
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Publication number: 20160124311Abstract: A method of forming a micro-electromechanical systems (MEMS) pixel, such as a DMD-type pixel, by depositing a photoresist spacer layer upon a substrate. The photoresist spacer layer is exposed to a grey-scale lithographic mask to shape an upper surface of the photoresist spacer layer. A control member is formed upon the shaped spacer layer, and has a sloped portion configured to maximize energy density. An image member is configured to be positioned as a function of the control member to form a spatial light modulator (SLM).Type: ApplicationFiled: November 3, 2014Publication date: May 5, 2016Inventors: Patrick I. Oden, James C. Baker, Sandra Zheng, William C. McDonald, Lance W. Barron
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Patent number: 9249651Abstract: Improved methods are provided for the application of downhole oil or gas well treating agents, such as liquid corrosion inhibition agents. The methods involve first lowering a liquid retainer device into a well casing, preferably at or above the location of the well production zone, followed by introduction of a liquid treating agent. The presence of the liquid retainer device prevents substantial passage of the agent into the production zone, and forms a column of the liquid agent above the device. The retainer device is then withdrawn from the well so as to create a substantially uniform film of the agent along the inner surfaces of the well casing. In this manner, proper coating of the casing is achieved while preventing production losses owing to passage of the treating agent into the production zone. The liquid retainer is preferably one or more swab cups or oil field retainers.Type: GrantFiled: May 28, 2013Date of Patent: February 2, 2016Assignee: Jacam Chemical Company 2013, LLCInventors: James C. Baker, Harlan G. McCormack, Gene F. Brock, Gene H. Zaid
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Publication number: 20150266727Abstract: A MEMS device is formed with facing surfaces of a contoured substrate and a layer of material having complementary contours. In one fabrication approach, a first photoresist layer is formed over a substrate. Selected regions of the first photoresist layer are exposed using a patterning mask. The exposed regions of the first photoresist layer are thermally shrunk to pattern the first photoresist layer with a contour. A layer of material is formed over the contoured first photoresist layer.Type: ApplicationFiled: March 18, 2015Publication date: September 24, 2015Inventors: James C. Baker, Patrick I. Oden, Robert S. Black
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Publication number: 20140352965Abstract: Improved methods are provided for the application of downhole oil or gas well treating agents, such as liquid corrosion inhibition agents. The methods involve first lowering a liquid retainer device into a well casing, preferably at or above the location of the well production zone, followed by introduction of a liquid treating agent. The presence of the liquid retainer device prevents substantial passage of the agent into the production zone, and forms a column of the liquid agent above the device. The retainer device is then withdrawn from the well so as to create a substantially uniform film of the agent along the inner surfaces of the well casing. In this manner, proper coating of the casing is achieved while preventing production losses owing to passage of the treating agent into the production zone. The liquid retainer is preferably one or more swab cups or oil field retainers.Type: ApplicationFiled: May 28, 2013Publication date: December 4, 2014Applicant: Jacam Chemical Company 2013, LLCInventors: James C. Baker, Harlan G. McCormack, Gene F. Brock, Gene H. Zaid
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Publication number: 20140316400Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a method of beginning an ablation procedure using a multi-electrode ablation system is described. The method includes selectively coupling the output of a power supply to a first electrode of a plurality of electrodes to increase a temperature at the first electrode to a first temperature set-point and limit a rate of increase of the temperature at the first electrode to a predetermined first rate.Type: ApplicationFiled: March 11, 2014Publication date: October 23, 2014Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Vincent Froehlich, Michael Olsen, Sukanya Varadharajan, Catherine A. Pipenhagen
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Publication number: 20140276765Abstract: Multi-electrode ablation systems, methods, and controllers are described. In one example, a multi-electrode ablation system includes a power supply configured to be coupled to a plurality of electrodes and a controller coupled to the power supply. The controller is configured to determine a thermal gain of each electrode of the plurality of electrodes. For each electrode of the plurality of electrodes, the controller sets a power limit based at least in part on said electrode's determined thermal gain. The power limit establishes a maximum power that may be dissipated through said electrode.Type: ApplicationFiled: March 11, 2014Publication date: September 18, 2014Inventors: John B. Blix, James C. Baker, Kevin K. Ennett, John Eric Hein, Joseph Allen Brotz, Joseph William Barnier, Raymond Victor Froehlich, Michael Olsen, Sukanya Varadharajan