Patents by Inventor Mathias Reimann
Mathias Reimann 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: 20240076439Abstract: The present invention relates to composition at least including (A) at least one epoxy-group terminated polyoxazolidinone, derived from at least one polyisocyanate compound and at least one aliphatic polyepoxide compound, (B) at least one compound having at least one group that is reactive towards terminal epoxy-groups, and (C) at least one solvent. The molar ratio of the epoxy groups of the polyepoxide compound to the isocyanate groups of the polyisocyanate compound is 50:1 to 2.4:1. The at least one epoxy-group terminated polyoxazolidinone is present in an amount of 50 to 95% by weight, in respect of the solid content of the composition. The sum of all components in respect of the solid content of the composition adds up to 100% by weight and where the solid content of the composition is at least 35% by weight.Type: ApplicationFiled: December 6, 2021Publication date: March 7, 2024Inventors: Irene Cristina Latorre Martinez, Yvonne Reimann, Jan Weikard, Florian Golling, Laura Woods, Christoph Guertler, Aurel Wolf, Kai Laemmerhold, Stefan Westhues, Sohajl Movahhed, Walter Leitner, Charlotte Over, Chicco Manzuna Sapu, Mathias Glassner
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Patent number: 11885892Abstract: A method for ascertaining output data of a global navigation satellite system (GNSS) locating device based on GNSS satellite signals in a vehicle, includes a) receiving surroundings data from the surroundings of the vehicle, b) generating a surroundings model to describe the surroundings of the vehicle using the surroundings data received in step a), c) receiving GNSS satellite signals from GNSS satellites using a GNSS receiver, and d) ascertaining output data of the GNSS locating device from the GNSS satellite signals received in step a). The surroundings model generated in step b) is used to compensate for anomalies caused by the surroundings of the propagation of the GNSS satellite signals from the GNSS satellites to the GNSS receiver.Type: GrantFiled: December 1, 2021Date of Patent: January 30, 2024Assignee: Robert Bosch GmbHInventor: Mathias Reimann
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Publication number: 20220179100Abstract: A method for ascertaining output data of a global navigation satellite system (GNSS) locating device based on GNSS satellite signals in a vehicle, includes a) receiving surroundings data from the surroundings of the vehicle, b) generating a surroundings model to describe the surroundings of the vehicle using the surroundings data received in step a), c) receiving GNSS satellite signals from GNSS satellites using a GNSS receiver, and d) ascertaining output data of the GNSS locating device from the GNSS satellite signals received in step a). The surroundings model generated in step b) is used to compensate for anomalies caused by the surroundings of the propagation of the GNSS satellite signals from the GNSS satellites to the GNSS receiver.Type: ApplicationFiled: December 1, 2021Publication date: June 9, 2022Inventor: Mathias Reimann
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Patent number: 10782312Abstract: A rotational acceleration sensor having a substrate, a mass movable with respect to the substrate, a suspension means suspending the mass movably relative to the substrate, a detection means for detecting a state of the mass deflected with respect to an idle position, and a detection means encompassing a first detection unit for detecting a deflected state of the mass i.e., a pivoting of the mass around a first axis substantially perpendicular to a principal extension plane of the substrate as a result of a rotational acceleration of the rotational acceleration sensor around the first axis. The detection means also encompassing a second detection unit for detecting a deflected state of the mass, i.e., a pivoting of the mass around a second axis substantially parallel to the principal extension plane of the substrate as a result of a rotational acceleration of the rotational acceleration sensor around the second axis.Type: GrantFiled: June 14, 2016Date of Patent: September 22, 2020Assignee: Robert Bosch GmbHInventor: Mathias Reimann
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Arrangement and method for detecting connection loss at a circuit part having a capacitive behaviour
Patent number: 10107851Abstract: The disclosure relates to an arrangement for detecting connection loss at a circuit part which has a capacitive behavior and is electrically connected to a useful signal source. The disclosure provides an evaluation circuit which is electrically connected to an input node of the circuit part having a capacitive behavior and detects the pulsed useful signal (UNUTZ), output by the useful signal source, at the input node of the circuit part having a capacitive behavior and evaluates the signal characteristics in order to detect connection loss.Type: GrantFiled: December 22, 2011Date of Patent: October 23, 2018Assignee: Robert Bosch GmbHInventor: Mathias Reimann -
Patent number: 9863781Abstract: A yaw rate sensor (10) includes a movable mass structure (12) and a drive component (13) which is suitable for setting the movable mass structure (12) in motion (14), and an analysis component (15) which is suitable for detecting a response (40) of the movable mass structure (12) to a yaw rate (?). A method for functional testing of a yaw rate sensor (10) includes the following steps: driving a movable mass structure (12), feeding a test signal (42) into a quadrature control loop (44) at a feed point (48) of the quadrature control loop (44), feeding back a deflection (40) of the movable mass structure (12), detecting a measure of the feedback of the movable mass structure (12), and reading out the response signal (47) from the quadrature control loop (44).Type: GrantFiled: November 13, 2014Date of Patent: January 9, 2018Assignee: ROBERT BOSCH GMBHInventors: Wolfram Bauer, Johannes Classen, Rainer Willig, Matthias Meier, Burkhard Kuhlmann, Mathias Reimann, Ermin Esch, Hans-Dieter Schwarz, Michael Veith, Christoph Lang, Udo-Martin Gomez
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Patent number: 9702742Abstract: A circuit assembly for plausibility checking of sensor signals, which can be generated by at least two separate sensor elements, includes at least one evaluation and control unit which receives the sensor signals via at least one interface unit and evaluates the received sensor signals for generating sensor data. A first evaluation and control unit is configured to receive the sensor signals of a first sensor element and to generate first sensor data from the first sensor signals. The first evaluation and control unit is configured to provide the generated first sensor data via at least one interface unit to a second evaluation and control unit, which receives and evaluates the sensor signals of a second sensor element to generate second sensor data. The second evaluation and control unit compares the generated second sensor data and the generated first sensor data to each other and inspects them for plausibility.Type: GrantFiled: June 11, 2012Date of Patent: July 11, 2017Assignee: Robert Bosch GmbHInventor: Mathias Reimann
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Publication number: 20160370402Abstract: A rotational acceleration sensor having a substrate, a mass movable with respect to the substrate, a suspension means suspending the mass movably relative to the substrate, a detection means for detecting a state of the mass deflected with respect to an idle position, and a detection means encompassing a first detection unit for detecting a deflected state of the mass i.e., a pivoting of the mass around a first axis substantially perpendicular to a principal extension plane of the substrate as a result of a rotational acceleration of the rotational acceleration sensor around the first axis. The detection means also encompassing a second detection unit for detecting a deflected state of the mass, i.e., a pivoting of the mass around a second axis substantially parallel to the principal extension plane of the substrate as a result of a rotational acceleration of the rotational acceleration sensor around the second axis.Type: ApplicationFiled: June 14, 2016Publication date: December 22, 2016Inventor: Mathias Reimann
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Publication number: 20150121990Abstract: A yaw rate sensor (10) includes a movable mass structure (12) and a drive component (13) which is suitable for setting the movable mass structure (12) in motion (14), and an analysis component (15) which is suitable for detecting a response (40) of the movable mass structure (12) to a yaw rate (?). A method for functional testing of a yaw rate sensor (10) includes the following steps: driving a movable mass structure (12), feeding a test signal (42) into a quadrature control loop (44) at a feed point (48) of the quadrature control loop (44), feeding back a deflection (40) of the movable mass structure (12), detecting a measure of the feedback of the movable mass structure (12), and reading out the response signal (47) from the quadrature control loop (44).Type: ApplicationFiled: November 13, 2014Publication date: May 7, 2015Inventors: Wolfram BAUER, Johannes CLASSEN, Rainer WILLIG, Matthias MEIER, Burkhard KUHLMANN, Mathias REIMANN, Ermin ESCH, Hans-Dieter SCHWARZ, Michael VEITH, Christoph LANG, Udo-Martin GOMEZ
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Patent number: 8938364Abstract: A sensor device includes: a sensor module mounted on a conductor board; a sensitive element which is sensitive to a variable; a self-test control unit implementing a self-test program, the self-test control unit applying a self-test variable to the sensitive element, taking the self-test program into account; a detection unit detecting a characteristic of the sensitive element which is altered as a result of the applied self-test variable and providing an actual self-test response, taking the altered characteristic into account; and a comparator unit provided on or in the sensor module, the comparator unit comparing the actual self-test response to at least one specified setpoint self-test response and providing comparative information.Type: GrantFiled: July 9, 2010Date of Patent: January 20, 2015Assignee: Robert Bosch GmbHInventors: Patrick Goerlich, Riad Stefo, Wolfram Bauer, Rainer Willig, Burkhard Kuhlmann, Mathias Reimann, Ermin Esch, Michael Baus, Gregor Wetekam, Michael Veith, Emma Abel, Wolfgang Fuerst
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Patent number: 8910518Abstract: A yaw rate sensor (10) includes a movable mass structure (12) and a drive component (13) which is suitable for setting the movable mass structure (12) in motion (14), and an analysis component (15) which is suitable for detecting a response (40) of the movable mass structure (12) to a yaw rate (?). A method for functional testing of a yaw rate sensor (10) includes the following steps: driving a movable mass structure (12), feeding a test signal (42) into a quadrature control loop (44) at a feed point (48) of the quadrature control loop (44), feeding back a deflection (40) of the movable mass structure (12), detecting a measure of the feedback of the movable mass structure (12), and reading out the response signal (47) from the quadrature control loop (44).Type: GrantFiled: April 6, 2010Date of Patent: December 16, 2014Assignee: Robert Bosch GmbHInventors: Wolfram Bauer, Johannes Classen, Rainer Willig, Matthias Meier, Burkhard Kuhlmann, Mathias Reimann, Ermin Esch, Hans-Dieter Schwarz, Michael Veith, Christoph Lang, Udo-Martin Gomez
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Publication number: 20140318209Abstract: A circuit assembly for plausibility checking of sensor signals, which can be generated by at least two separate sensor elements, includes at least one evaluation and control unit which receives the sensor signals via at least one interface unit and evaluates the received sensor signals for generating sensor data. A first evaluation and control unit is configured to receive the sensor signals of a first sensor element and to generate first sensor data from the first sensor signals. The first evaluation and control unit is configured to provide the generated first sensor data via at least one interface unit to a second evaluation and control unit, which receives and evaluates the sensor signals of a second sensor element to generate second sensor data. The second evaluation and control unit compares the generated second sensor data and the generated first sensor data to each other and inspects them for plausibility.Type: ApplicationFiled: June 11, 2012Publication date: October 30, 2014Applicant: Robert Bosch GmbHInventor: Mathias Reimann
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Patent number: 8786419Abstract: A device for controlling a device by using a rotation-rate sensor. In order to provide a device for determining a triggering signal for a safety device which allows a particularly compact implementation of the device, the device is set up to ascertain an acceleration variable on the basis of a first sensor signal for a first seismic mass of the rotation-rate sensor and the second sensor signal for a second seismic mass of the rotation-rate sensor and to control the device as a function of the acceleration variable.Type: GrantFiled: November 3, 2009Date of Patent: July 22, 2014Assignee: Robert Bosch GmbHInventors: Markus Ulm, Mathias Reimann, Harald Emmerich, Udo-Martin Gomez, Emma Abel
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Arrangement and Method for Detecting Connection Loss at a Circuit Part having a Capacitive Behaviour
Publication number: 20140043041Abstract: The disclosure relates to an arrangement for detecting connection loss at a circuit part which has a capacitive behaviour and is electrically connected to a useful signal source. The disclosure provides an evaluation circuit which is electrically connected to an input node of the circuit part having a capacitive behaviour and detects the pulsed useful signal (UNUTZ), output by the useful signal source, at the input node of the circuit part having a capacitive behaviour and evaluates the signal characteristics in order to detect connection loss.Type: ApplicationFiled: December 22, 2011Publication date: February 13, 2014Applicant: ROBERT BOSCH GMBHInventor: Mathias Reimann -
Publication number: 20120186345Abstract: A yaw rate sensor (10) includes a movable mass structure (12) and a drive component (13) which is suitable for setting the movable mass structure (12) in motion (14), and an analysis component (15) which is suitable for detecting a response (40) of the movable mass structure (12) to a yaw rate (?). A method for functional testing of a yaw rate sensor (10) includes the following steps: driving a movable mass structure (12), feeding a test signal (42) into a quadrature control loop (44) at a feed point (48) of the quadrature control loop (44), feeding back a deflection (40) of the movable mass structure (12), detecting a measure of the feedback of the movable mass structure (12), and reading out the response signal (47) from the quadrature control loop (44).Type: ApplicationFiled: April 6, 2010Publication date: July 26, 2012Inventors: Wolfram Bauer, Johannes Classen, Rainer Willig, Matthias Meier, Burkhard Kuhlmann, Matthias Mathias Reimann, Ermin Esch, Hans-Dieter Schwarz, Michael Veith, Christoph Lang, Udo-Martin Gomez
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Publication number: 20110066396Abstract: A sensor device includes: a sensor module mounted on a conductor board; a sensitive element which is sensitive to a variable; a self-test control unit implementing a self-test program, the self-test control unit applying a self-test variable to the sensitive element, taking the self-test program into account; a detection unit detecting a characteristic of the sensitive element which is altered as a result of the applied self-test variable and providing an actual self-test response, taking the altered characteristic into account; and a comparator unit provided on or in the sensor module, the comparator unit comparing the actual self-test response to at least one specified setpoint self-test response and providing comparative information.Type: ApplicationFiled: July 9, 2010Publication date: March 17, 2011Inventors: Patrick Goerlich, Riad Stefo, Wolfram Bauer, Rainer Willig, Burkhard Kuhlmann, Mathias Reimann, Ermin Esch, Michael Baus, Gregor Wetekam, Michael Veith, Emma Abel, Wolfgang Fuerst
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Publication number: 20100225500Abstract: A device for controlling a device by using a rotation-rate sensor. In order to provide a device for determining a triggering signal for a safety device which allows a particularly compact implementation of the device, the device is set up to ascertain an acceleration variable on the basis of a first sensor signal for a first seismic mass of the rotation-rate sensor and the second sensor signal for a second seismic mass of the rotation-rate sensor and to control the device as a function of the acceleration variable.Type: ApplicationFiled: November 3, 2009Publication date: September 9, 2010Inventors: Markus ULM, Mathias Reimann, Harald Emmerich, Udo-Martin Gomez, Emma Abel
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Patent number: 7535325Abstract: A component is provided for an impedance change in a coplanar waveguide which includes two grounding conductors and a signal line lying between the grounding conductors, as well as a conducting connecting element, which has a covering surface for the two grounding conductors and the signal line, and is electrically insulated, so that in each case a capacitor is formed. The connecting element and the lines are situated and arranged so that the respective capacitor between the grounding conductors and the connecting element has an invariable capacitance, but the capacitor between the connecting element and the signal line has a variable capacitance. A structure is also provided in which in an exactly opposite way, the respective capacitor between the grounding conductors and the connecting element has a variable capacitance, but the capacitor between the connecting element and the signal line has an invariable capacitance. Furthermore, a method for producing such a component is also provided.Type: GrantFiled: July 24, 2004Date of Patent: May 19, 2009Assignee: Robert Bosch GmbHInventors: Roland Mueller-Fiedler, Markus Ulm, Mathias Reimann, Thomas Buck
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Publication number: 20070229198Abstract: A component is provided for an impedance change in a coplanar waveguide which includes two grounding conductors and a signal line lying between the grounding conductors, as well as a conducting connecting element, which has a covering surface for the two grounding conductors and the signal line, and is electrically insulated, so that in each case a capacitor is formed. The connecting element and the lines are situated and arranged so that the respective capacitor between the grounding conductors and the connecting element has an invariable capacitance, but the capacitor between the connecting element and the signal line has a variable capacitance. A structure is also provided in which in an exactly opposite way, the respective capacitor between the grounding conductors and the connecting element has a variable capacitance, but the capacitor between the connecting element and the signal line has an invariable capacitance. Furthermore, a method for producing such a component is also provided.Type: ApplicationFiled: July 24, 2004Publication date: October 4, 2007Inventors: Roland Mueller-Fiedler, Markus Ulm, Mathias Reimann, Thomas Buck
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Publication number: 20060097388Abstract: An electrical component is proposed, in particular a high-frequency microelectronic or microelectromechanical component having a base element that is provided with a feedthrough, a first conductive structure extending on an upper side of the base element being connected by the feedthrough, continuously for high-frequency electromagnetic waves, to a second conductive structure extending on a lower side of the base element. The feedthrough has the form of a right prism or cylinder, and the first and/or the second conductive structure is embodied as a planar waveguide, in particular as a coplanar waveguide.Type: ApplicationFiled: June 24, 2003Publication date: May 11, 2006Inventors: Klaus Breitschwerdt, Markus Ulm, Andrea Urban, Mathias Reimann