Patents by Inventor Matthew J. Schneider
Matthew J. Schneider 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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Publication number: 20240175462Abstract: A steering shaft assembly includes a shaft having a first end region including a nose, a male spline region coupleable with a female spline region of a clamp yoke, a ring flag seat adjacent said nose, and a first ring flag locating feature between said ring flag seat and said male spline region. The steering shaft assembly also includes a ring flag having an annular band seated on said ring flag seat, a flag extending axially from said annular band in a first direction beyond said first end and radially outwardly from said annular band, and a second ring flag locating feature extending axially from said annular band in a second direction opposite said first direction, said second ring flag locating feature interacting with said first ring flag locating feature to orient said ring flag in a predetermined rotational orientation relative to said shaft.Type: ApplicationFiled: November 28, 2023Publication date: May 30, 2024Inventors: Matthew L. Messing, Douglas M. Schneider, Steven R. Burk, Robert J. Smith, Phillip D. Beckman, JR., Bruce D. Kniebbe
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Publication number: 20240164937Abstract: Disclosed herein are female external catheters (“FECs”) and methods thereof. For example, an FEC can include a catheter body, a catheter back, and a connector. The catheter body can include a cavity extending along a length of the catheter body. The cavity is configured to open toward a patient. The catheter back can include a connector hole aligned with an end portion of the cavity. The connector hole can be configured to open away from the patient. The connector is disposed in the connector hole. The connector can include a sump configured to collect urine from the end portion of the cavity for withdrawal from the FEC. In another example, a method of an FEC can includes a method of using the FEC.Type: ApplicationFiled: March 30, 2022Publication date: May 23, 2024Inventors: D. Claire Gloeckner, Matthew J. Rothberg, Seth C. Schneider, Jonathan Robichaud, Michael Bailey, James David Hughett, SR.
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Patent number: 11963691Abstract: A surgical instrument, has an end effector that includes an ultrasonic blade, and a clamp arm that moves relative to the ultrasonic blade from an opened position toward an intermediate position and a closed position. The clamp arm is offset from the ultrasonic blade to define a predetermined gap in the intermediate position between the opened position and the closed position. A clamp arm actuator connects to the clamp arm and moves from an opened configuration to a closed configuration to direct the clamp arm from the opened position toward the intermediate position and the closed position. A spacer connects with the clamp arm to inhibit movement of the clamp arm from the intermediate position toward the closed position for maintaining the predetermined gap between the clamp arm and the ultrasonic blade.Type: GrantFiled: December 21, 2020Date of Patent: April 23, 2024Assignee: Cilag GmbH InternationalInventors: Ryan M. Asher, Brian D. Black, John E. Brady, Joseph Dennis, Geni M. Giannotti, Bryce L. Heitman, Timothy S. Holland, Joseph E. Hollo, Andrew Kolpitcke, Amy M. Krumm, Jason R. Lesko, Matthew C. Miller, David A. Monroe, Ion V. Nicolaescu, Rafael J. Ruiz Ortiz, Matthew S. Schneider, Richard C. Smith, Shawn C. Snyder, Sarah A. Worthington, Monica L. Rivard, Fajian Zhang
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Publication number: 20240064218Abstract: Various systems and methods for implementing a software defined industrial system are described herein. For example, an orchestrated system of distributed nodes may run an application, including modules implemented on the distributed nodes. In response to a node failing, a module may be redeployed to a replacement node. In an example, self-descriptive control applications and software modules are provided in the context of orchestratable distributed systems. The self-descriptive control applications may be executed by an orchestrator or like control device and use a module manifest to generate a control system application. For example, an edge control node of the industrial system may include a system on a chip including a microcontroller (MCU) to convert IO data. The system on a chip includes a central processing unit (CPU) in an initial inactive state, which may be changed to an activated state in response an activation signal.Type: ApplicationFiled: July 26, 2023Publication date: February 22, 2024Inventors: Rita H. Wouhaybi, John Vicente, Kirk Smith, Robert Chavez, Mark Yarvis, Steven M. Brown, Jeremy Ouillette, Roderick E. Kronschnabel, Matthew J. Schneider, Chris D. Lucero, Atul N. Hatalkar, Sharad K. Garg, Casey Rathbone, Aaron R. Berck, Xubo Zhang, Ron Kuruvilla Thomas, Mandeep Shetty, Ansuya Negi
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Patent number: 11758031Abstract: Various systems and methods for implementing a software defined industrial system are described herein. For example, an orchestrated system of distributed nodes may run an application, including modules implemented on the distributed nodes. In response to a node failing, a module may be redeployed to a replacement node. In an example, self-descriptive control applications and software modules are provided in the context of orchestratable distributed systems. The self-descriptive control applications may be executed by an orchestrator or like control device and use a module manifest to generate a control system application. For example, an edge control node of the industrial system may include a system on a chip including a microcontroller (MCU) to convert IO data. The system on a chip includes a central processing unit (CPU) in an initial inactive state, which may be changed to an activated state in response an activation signal.Type: GrantFiled: May 9, 2022Date of Patent: September 12, 2023Assignee: Intel CorporationInventors: Rita H. Wouhaybi, John Vicente, Kirk Smith, Robert Chavez, Mark Yarvis, Steven M. Brown, Jeremy Ouillette, Roderick E. Kronschnabel, Matthew J. Schneider, Chris D. Lucero, Atul N. Hatalkar, Sharad K. Garg, Casey Rathbone, Aaron R. Berck, Xubo Zhang, Ron Kuruvilla Thomas, Mandeep Shetty, Ansuya Negi
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Publication number: 20220360653Abstract: Various systems and methods for implementing a software defined industrial system are described herein. For example, an orchestrated system of distributed nodes may run an application, including modules implemented on the distributed nodes. In response to a node failing, a module may be redeployed to a replacement node. In an example, self-descriptive control applications and software modules are provided in the context of orchestratable distributed systems. The self-descriptive control applications may be executed by an orchestrator or like control device and use a module manifest to generate a control system application. For example, an edge control node of the industrial system may include a system on a chip including a microcontroller (MCU) to convert IO data. The system on a chip includes a central processing unit (CPU) in an initial inactive state, which may be changed to an activated state in response an activation signal.Type: ApplicationFiled: May 9, 2022Publication date: November 10, 2022Inventors: Rita H. Wouhaybi, John Vicente, Kirk Smith, Robert Chavez, Mark Yarvis, Steven M. Brown, Jeremy Ouillette, Roderick E. Kronschnabel, Matthew J.` Schneider, Chris D. Lucero, Atul N. Hatalkar, Shara K. Garg, Casey Rathbone, Aaron R. Berck, Xubo Zhang, Ron Kuruvilla Thomas, Mandeep Shetty, Ansuya Negi
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Patent number: 11330087Abstract: Various systems and methods for implementing a software defined industrial system are described herein. For example, an orchestrated system of distributed nodes may run an application, including modules implemented on the distributed nodes. In response to a node failing, a module may be redeployed to a replacement node. In an example, self-descriptive control applications and software modules are provided in the context of orchestratable distributed systems. The self-descriptive control applications may be executed by an orchestrator or like control device and use a module manifest to generate a control system application. For example, an edge control node of the industrial system may include a system on a chip including a microcontroller (MCU) to convert IO data. The system on a chip includes a central processing unit (CPU) in an initial inactive state, which may be changed to an activated state in response an activation signal.Type: GrantFiled: September 28, 2018Date of Patent: May 10, 2022Assignee: Intel CorporationInventors: Rita H. Wouhaybi, John Vicente, Kirk Smith, Robert Chavez, Mark Yarvis, Steven M. Brown, Jeremy Ouillette, Roderick E. Kronschnabel, Matthew J. Schneider, Chris D. Lucero, Atul N. Hatalkar, Sharad Garg, Casey Rathbone, Aaron R. Berck, Xubo Zhang, Ron Kuruvilla Thomas, Mandeep Shetty, Ansuya Negi
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Patent number: 11112521Abstract: A capacitive proximity sensor may include a proximity sensing capacitor to provide a voltage output based on a voltage input, the capacitor including a ground plane and an electrode loop capacitively coupled to the ground plane. The proximity sensor may include a processor to detect an object proximity based on a change in the voltage output. This proximity sensor provides automated detection of a person, and thereby reduces the need for a vehicle occupant or child caregiver to activate a sensor by pressing a button. The use of a capacitance-based proximity sensor reduces issues associated with fabric, clothing, or other materials separating the proximity sensor from a person.Type: GrantFiled: June 18, 2019Date of Patent: September 7, 2021Assignee: Intel CorporationInventors: Marcie M. Miller, Roderick E. Kronschnabel, Matthew J. Schneider, Rene J. Sanchez, Christopher L. Ross, Ryan R. Carnaghi, Keith A. Swesey, Kevin Edwards, Steven W. Whitehorn, Cecilia Yancy, Thomas V. Moss
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Publication number: 20200310394Abstract: Various systems and methods for implementing a software defined industrial system are described herein. For example, an orchestrated system of distributed nodes may run an application, including modules implemented on the distributed nodes. In response to a node failing, a module may be redeployed to a replacement node. In an example, self-descriptive control applications and software modules are provided in the context of orchestratable distributed systems. The self-descriptive control applications may be executed by an orchestrator or like control device and use a module manifest to generate a control system application. For example, an edge control node of the industrial system may include a system on a chip including a microcontroller (MCU) to convert IO data. The system on a chip includes a central processing unit (CPU) in an initial inactive state, which may be changed to an activated state in response an activation signal.Type: ApplicationFiled: September 28, 2018Publication date: October 1, 2020Applicant: Intel CorporationInventors: Rita H. Wouhaybi, Jonh Vicente, Kirk Smith, Robert Chavez, Mark Yarvis, Steven M. Brown, Jeremy Ouilette, Roderick E. Kronschnabel, Matthew J. Schneider, Chris D. Lucero, Atul N. Hatalkar, Sharad Garg, Casey Rathbone, Aaron R. Berck, Xubo Zhang, Ron Kuruvilla Thomas, Mandeep Shetty, Ansuya Negi
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Publication number: 20200142088Abstract: A capacitive proximity sensor may include a proximity sensing capacitor to provide a voltage output based on a voltage input, the capacitor including a ground plane and an electrode loop capacitively coupled to the ground plane. The proximity sensor may include a processor to detect an object proximity based on a change in the voltage output. This proximity sensor provides automated detection of a person, and thereby reduces the need for a vehicle occupant or child caregiver to activate a sensor by pressing a button. The use of a capacitance-based proximity sensor reduces issues associated with fabric, clothing, or other materials separating the proximity sensor from a person.Type: ApplicationFiled: June 18, 2019Publication date: May 7, 2020Inventors: Marcie M. Miller, Roderick E. Kronschnabel, Matthew J. Schneider, Rene J. Sanchez, Christopher L. Ross, Ryan R. Carnaghi, Keith A. Swesey, Kevin Edwards, Steven W. Whitehorn, Cecilia Yancy, Thomas V. Moss
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Patent number: 10324213Abstract: A capacitive proximity sensor may include a proximity sensing capacitor to provide a voltage output based on a voltage input, the capacitor including a ground plane and an electrode loop capacitively coupled to the ground plane. The proximity sensor may include a processor to detect an object proximity based on a change in the voltage output. This proximity sensor provides automated detection of a person, and thereby reduces the need for a vehicle occupant or child caregiver to activate a sensor by pressing a button. The use of a capacitance-based proximity sensor reduces issues associated with fabric, clothing, or other materials separating the proximity sensor from a person.Type: GrantFiled: December 21, 2016Date of Patent: June 18, 2019Assignee: Intel CorporationInventors: Marcie M. Miller, Roderick E. Kronschnabel, Matthew J. Schneider, Rene J. Sanchez, Christopher L. Ross, Ryan R. Carnaghi, Keith A. Swesey, Kevin Edwards, Steven W. Whitehorn, Cecilia Yancy, Thomas V. Moss
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Publication number: 20180354443Abstract: A system and method for child car seat safety detection and notification are disclosed. A particular embodiment is configured to: provide at least one sensor to measure a condition present in an environment in which a child is restrained in a child car seat in a vehicle; determine, based on sensor data from the sensor, if the condition requires a notification to be sent to a user; generate a notification message including at least a portion of the sensor data and information indicative of a location of the child car seat; send the notification message to a mobile device application; and send the notification message to a vehicle subsystem application.Type: ApplicationFiled: December 18, 2015Publication date: December 13, 2018Inventors: Nona Ebrahimi, Joseph M. Romeo, Christopher L. Ross, Rene J. Sanchez, Marcie M. Miller, Jill C. Sciarappo, Amarnath Kona, Shubhada H. Sahasrabudhe, Matthew J. Schneider, Rod E. Kronschnabel, Thomas V. Moss, Steven Whitehorn, Kevin Edwards, Keith A. Swesey, Cecilia Yancy, Camilo F. Gomez
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Publication number: 20180059279Abstract: A capacitive proximity sensor may include a proximity sensing capacitor to provide a voltage output based on a voltage input, the capacitor including a ground plane and an electrode loop capacitively coupled to the ground plane. The proximity sensor may include a processor to detect an object proximity based on a change in the voltage output. This proximity sensor provides automated detection of a person, and thereby reduces the need for a vehicle occupant or child caregiver to activate a sensor by pressing a button. The use of a capacitance-based proximity sensor reduces issues associated with fabric, clothing, or other materials separating the proximity sensor from a person.Type: ApplicationFiled: December 21, 2016Publication date: March 1, 2018Inventors: Marcie M. Miller, Roderick E. Kronschnabel, Matthew J. Schneider, Rene J. Sanchez, Christopher L. Ross, Ryan R. Carnaghi, Keith A. Swesey, Kevin Edwards, Steven W. Whitehorn, Cecilia Yancy, Thomas V. Moss