Robert Bosch GmbH patent applications on February 15th, 2024
Patent Applications by Robert Bosch GmbH on February 15th, 2024
Robert Bosch GmbH: 31 patent applications
Robert Bosch GmbH has applied for patents in the areas of H04W64/00 (5), H01M8/04082 (3), G06F13/42 (3), H04W72/40 (2), F16K31/54 (2)
With keywords such as: device, unit, data, terminal, transmission, control, fuel, cell, energy, and position in patent application abstracts.
Patent Applications by Robert Bosch GmbH
20240051086.Material Collection Device_simplified_abstract_(robert bosch gmbh)
Inventor(s): Florian Esenwein of Leinfelden-Echterdingen (DE) for robert bosch gmbh, Simon Riggenmann of Stuttgart (DE) for robert bosch gmbh, Adamo Sadikovic of Renningen (DE) for robert bosch gmbh
IPC Code(s): B24B55/10
Abstract: a material collection device for a hand-held power tool includes a material collection container for collecting material removed during operation of the hand-held power tool. at least one opening of the material collection container is for feeding the material into the material collection container and is arranged in an opening plane. at least one mounting unit is for mounting the material collection container on the hand-held power tool. the at least one mounting unit includes a channel element for connection to an ejection port of the hand-held power tool. a channel longitudinal axis of the channel element is arranged transversely to the opening plane of the material collection container in at least one section plane running perpendicularly to the opening plane.
Inventor(s): Philipp Brechel of Stuttgart (DE) for robert bosch gmbh, Adrian Haug of Leonberg (DE) for robert bosch gmbh, Christoph Senneka of Speyer (DE) for robert bosch gmbh, Dieter Bruss of Aidlingen (DE) for robert bosch gmbh, Martin Karle of Leinfelden-Echterdingen (DE) for robert bosch gmbh, Robert Schumann of Stuttgart (DE) for robert bosch gmbh, Silke Bruening of Schwieberdingen (DE) for robert bosch gmbh, Thomas Kroker of Aidlingen-Deufringen (DE) for robert bosch gmbh, Wei Ling of Renningen (DE) for robert bosch gmbh
IPC Code(s): B60R16/03
Abstract: a control device for a motor vehicle. in the event of an interruption of an external voltage supply, limited functionality can continue to be maintained. for this purpose, it is provided to deactivate some functional modules of the control device in the event of an interruption of the external supply voltage and to use electrical energy stored in the deactivated functional modules for the voltage supply of further functional modules.
Inventor(s): Gian Antonio D' Addetta of Stuttgart (DE) for robert bosch gmbh, Heiko Freienstein of Weil Der Stadt (DE) for robert bosch gmbh, Joram Berger of Heimsheim (DE) for robert bosch gmbh, Laszlo Boros of Ludwigsburg (DE) for robert bosch gmbh
IPC Code(s): B60T8/1761, B60T13/16, B60T7/22
Abstract: a brake system for a motor vehicle. the brake system includes an autonomous emergency braking system to ascertain an object list using sensor data and continuously update the object list based on newly added sensor data, to ascertain a braking event based on the object list at a first point in time and to activate the actuating device to generate a hydraulic force if a braking event is ascertained, to recognize whether the braking event is still present based on the updated object list at a second point in time, after the first point in time; and to activate the hydraulic unit directly to reduce the hydraulic force applied to at least one wheel brake of the motor vehicle if the braking event is no longer present.
Inventor(s): Jonathan Juergens of Stuttgart (DE) for robert bosch gmbh, Andreas Zoebele of Markgroeningen (DE) for robert bosch gmbh, Jochen Steinmann of Loewenstein (DE) for robert bosch gmbh, Jochen Staack of Winnenden (DE) for robert bosch gmbh
IPC Code(s): B60W30/20, B60W30/18, B60W10/08, B60W10/196, B60W10/184, B60L7/18, B60L7/26
Abstract: in a method for braking a vehicle with the aid of at least one electric machine, operated as a generator, of the vehicle, a torque generated by the electric machine is controlled by a damping control function in order to reduce a periodic deflection of a drive train, coupled to a rotor shaft of the electric machine, relative to the rotor shaft. furthermore, a braking request signal representing a target braking torque is detected, a deactivation condition for deactivating the damping control function is identified on the basis of the braking request signal, the damping control function is deactivated when a deactivation condition is identified, a braking torque is generated based on the braking request signal by operating the electric machine as a generator, a reactivation condition for reactivating the damping control function is identified during the process of generating the braking torque, and the damping control function is reactivated when the reactivation condition is identified.
20240051597.Method for Operating a Vehicle, and Vehicle_simplified_abstract_(robert bosch gmbh)
Inventor(s): Christian Guenther of Mutlangen (DE) for robert bosch gmbh
IPC Code(s): B62D5/04, B60W50/08
Abstract: the disclosure relates to a method for operating a vehicle, in particular a motor vehicle. the vehicle comprises a steering system with a steering handle, an actuator unit which is operatively connected to the steering handle, and at least one torque sensor, which is paired with the actuator unit, for detecting a torque signal.
20240051597.Method for Operating a Vehicle, and Vehicle_simplified_abstract_(robert bosch gmbh)
Inventor(s): Christian Guenther of Mutlangen (DE) for robert bosch gmbh
IPC Code(s): B62D5/04, B60W50/08
Abstract: according to the disclosure, a compensation torque which correlates to a systematic sensor offset of the torque sensor is ascertained in a calibration operational state and is superimposed onto the torque signal in an automated drive operation state in order to monitor a contact of the steering handle.
Inventor(s): Dennis Mehlo of Taichung City (TW) for robert bosch gmbh, Lei Chen of Taichung City (TW) for robert bosch gmbh, Thilo Koeder of Gerlingen (DE) for robert bosch gmbh, Thorsten Droigk of Tuebingen (DE) for robert bosch gmbh, Vikram Anil Godbole of Echterdingen (DE) for robert bosch gmbh
IPC Code(s): B62M6/90, B62M6/55, B62J43/28, B62J43/13
Abstract: an electric bicycle includes an electric drive, at least one frame tube having an interior, an electrical energy store arranged in the interior of the frame tube, and a holding device configured to establish a connection between the electrical energy store and the frame tube. the frame tube in the interior has a receiving portion for receiving the electrical energy store. the holding device is configured to fix the electrical energy store in the interior to the frame tube and has no electrical contacts. additionally, the holding device fixes the electrical energy store in the frame tube at least by a radial force, and the holding device is connected to the electrical energy store without a screw connection.
Inventor(s): Adrien Dulac of Stuttgart (DE) for robert bosch gmbh, Joshua Emanuel Weiss of Flein (DE) for robert bosch gmbh, Michael Stein of Loechgau (DE) for robert bosch gmbh
IPC Code(s): F02D35/00, F02D33/02
Abstract: a method for limiting an air charge of an internal combustion engine. a maximum permissible pre-controlled charge and an exhaust-gas temperature-dependent delta charge are determined by means of a pi controller. a total permissible charge is determined on the basis of the maximum permissible pre-controlled charge and the exhaust-gas temperature-dependent delta-charge, and the air charge of the internal combustion engine is limited by the total permissible charge.
Inventor(s): Johannes Schwacke of Bad Orb (DE) for robert bosch gmbh, Nicolas Englert of Lohr (DE) for robert bosch gmbh
IPC Code(s): F15B15/28, F15B15/10
Abstract: a detection device is for detecting a position of a piston in a cylinder barrel and/or for detecting a strain on the cylinder barrel. the cylinder barrel includes a strain gauge. the detection device includes a reading interface configured to read a strain gauge signal from the strain gauge and an evaluation unit configured to evaluate the position of the piston and/or the strain on the cylinder barrel using the strain gauge signal.
Inventor(s): Markus Kubacki of Wuerzburg (DE) for robert bosch gmbh, Alexandre Orth of Hettstadt (DE) for robert bosch gmbh, Gottfried Hendrix of Gemuenden (DE) for robert bosch gmbh
IPC Code(s): F16K31/163, F16K31/54
Abstract: the disclosure relates to a transmission unit, having (i) a housing for the fluid-tight encapsulation of at least one part of the transmission unit, (ii) a rack and pinion transmission which is arranged in the housing and has at least one gear rack, (iii) a hydraulic drive system, which is arranged in the housing, has at least one displacer unit for increasing the energy of a pressurizable working fluid of the hydraulic drive system, and has at least one chamber in which a piston, operatively connected to a gear rack of the rack and pinion transmission, can be moved using the working fluid in order to effect a linear movement of the gear rack, and (iv) a rotatable mechanical actuator, which is operatively connected to the pinion of the rack and pinion transmission and is arranged outside the housing at least in portions.
Inventor(s): Shi Deng of Shanghai (CN) for robert bosch gmbh, Mingang Wang of Shanghai (CN) for robert bosch gmbh
IPC Code(s): G01M13/00, G05B23/02
Abstract: a method for identifying an abnormality in a mechanical apparatus or mechanical component includes: i) acquiring at least two classes of undersampled measurement data collected in or on a mechanical apparatus or mechanical component, all of the at least two classes of undersampled measurement data being different from one another in either one of or both of the following aspects: delay relative to occurrence time of a trigger event, and sampling frequency; and ii) based on the at least two classes of undersampled measurement data acquired, using an abnormality identification model to identify an abnormality in the mechanical apparatus or mechanical component, the abnormality identification model being based on machine learning and used for identifying an abnormality in the mechanical apparatus or mechanical component. also disclosed is a method for training an abnormality identification model based on machine learning, a computer apparatus, a computer program product, and a detection apparatus. the above provides a fault diagnosis or predictive maintenance solution which is cost-effective and gives reliable results.
20240053296.Method for Operating a Wide-Band Lambda Probe_simplified_abstract_(robert bosch gmbh)
Inventor(s): Bernhard Ledermann of Weil Der Stadt (DE) for robert bosch gmbh, Hanna Huber of Stuttgart (DE) for robert bosch gmbh, Ralf Zimmerschied of Darmstadt (DE) for robert bosch gmbh
IPC Code(s): G01N27/417, G01M15/10, G01N27/419, F04B43/04
Abstract: a method for operating a wide-band lambda probe. the method includes controlling the nernst voltage to a predefined setpoint value by setting the pump voltage and/or the pump current, measuring the pump voltage and/or the pump current and/or the lambda value, forming measured value pairs based on measured measuring values of the pump voltage, the pump current and/or the lambda value, calculating a regression line based on the measured value pairs in order to approximate a predefined part of a reference characteristic curve of the pump voltage, and ascertaining a pump current offset and/or lambda offset based on the regression line.
20240053493.METHOD AND APPARATUS FOR A TERMINAL DEVICE_simplified_abstract_(robert bosch gmbh)
Inventor(s): Khaled Shawky Hassan of Sarstedt (DE) for robert bosch gmbh, Maximilian Stark of Hamburg (DE) for robert bosch gmbh
IPC Code(s): G01S19/42, G01S19/39, G01S5/00, H04W4/02, H04W64/00, H04L5/00
Abstract: a computer-implemented method for a terminal device. the method includes: providing, by a terminal device, a first information characterizing a position of the terminal device, performing at least one sidelink-based positioning procedure associated with at least one further terminal device.
Inventor(s): Jens Dorfmueller of Magstadt (DE) for robert bosch gmbh
IPC Code(s): G02B27/62, H04N17/00
Abstract: a method for producing a camera. the method includes: providing prefabricated components; adjusting at least two of these prefabricated components relative to one another in accordance with at least one specified optimality criterion; and adhesively bonding the components to one another in the adjusted state; wherein prior data characterizing a specific specimen of at least one of the prefabricated components, and/or measured data in respect of the optical performance of the combination of the components adjusted with respect to one another, are mapped by a trained machine learning model onto a prediction for the optical performance that the camera will deliver once it has run through at least one additional production step after the adhesive bonding; and this prediction is used as feedback for an influencing action on the production process.
Inventor(s): Mark Herrmann of Radebeul (DE) for robert bosch gmbh
IPC Code(s): G05B19/418
Abstract: a method is for identifying at least one variable from a plurality of variables having a dependence on a predetermined variable from the plurality of variables. the method includes providing a data set having data points for the plurality of variables for a plurality of products respectively and a selection of the predetermined variable from the plurality of variables. the method further includes pre-processing the data set, training a machine learning system on the pre-processed data set, and determining the dependencies of the variables on the predetermined variable based on the trained machine learning system.
20240054093.METHOD FOR PERFORMING DATA TRANSMISSION_simplified_abstract_(robert bosch gmbh)
Inventor(s): Andreas Enns of Kirchheim Am Neckar (DE) for robert bosch gmbh, Daniele Ambrosio of Stuttgart (DE) for robert bosch gmbh
IPC Code(s): G06F13/42, G06F13/40
Abstract: a method for performing data transmission between a control device and an electronic unit. a control unit and a flexray transceiver are provided in the control device and a control unit and a flexray transceiver also being provided in the electronic unit. a flexray link is used as a physical route for data transmission and the data transmission is performed using the uart protocol.
20240054095.METHOD FOR PERFORMING A DATA TRANSMISSION_simplified_abstract_(robert bosch gmbh)
Inventor(s): Andreas Enns of Kirchheim Am Neckar (DE) for robert bosch gmbh, Florian Schrittwieser of Stuttgart (DE) for robert bosch gmbh
IPC Code(s): G06F13/42, G06F13/40, G06F13/28
Abstract: a method for performing a data transmission between a control device and an electronics unit. a microcontroller and an ethernet transceiver are provided in the control unit, and a microcontroller and an ethernet transceiver are also provided in the electronics unit. for data transmission, the two ethernet transceivers are first synchronized, taking into account a common clock cycle, and, for data transmission, an ethernet connection is used as a physical route, and the data transmission is carried out with a serial protocol.
Inventor(s): Anh Tuan Tran of Heilbronn (DE) for robert bosch gmbh
IPC Code(s): G06V20/58, G08G1/01
Abstract: a method for generating a rules package describing the current traffic situation of a motor vehicle. a traffic sign recognition unit monitors the area in front of the motor vehicle, and is used to generate video data. traffic signs are recognized and an encoder/decoder unit generates first sensor data and transmits them to an evaluation unit, which encodes the recognized traffic sign. as a function of the first sensor data, the evaluation unit requests second sensor data, which characterize the current traffic situation, from at least one further sensor. in response, the encoder/decoder unit encodes these second sensor data, transmits them to the evaluation unit and the latter compares them along with the first sensor data to traffic rules stored in a database. individual traffic rules are selected and from the selected rules. a rules package is created which contains the selected traffic rules.
Inventor(s): Sebastian Bayer of Schoenaich (DE) for robert bosch gmbh, Michel Janus of Kirchentellinsfurt (DE) for robert bosch gmbh
IPC Code(s): H01L21/66
Abstract: a method is for determining a reduced first amount of testing from a second amount of testing. the method includes provision of a binary matrix, and optimization of a cost function, which is dependent on test variables. each of test of the second amount of testing is associated with a test variable, and the test variable characterizes whether the test is relevant. the cost function defines constraints: a first constraint is defined in that a result of a matrix/vector multiplication must be greater than or equal to a vector comprising only ones. the matrix of the matrix/vector multiplication is a matrix whose entries all have the value one. the entries of the binary matrix are subtracted, and the vector of matrix/vector multiplication is a vector comprising the test variables. a second constraint is defined in that the test variables are binary.
Inventor(s): Jens Baringhaus of Sindelfingen (DE) for robert bosch gmbh, Daniel Krebs of Aufhausen (DE) for robert bosch gmbh, Dick Scholten of Stuttgart (DE) for robert bosch gmbh
IPC Code(s): H01L29/78, H01L29/66, H01L29/417
Abstract: a vertical field-effect transistor. the transistor includes: a drift region having a first conductivity type; a semiconductor fin on or over the drift region; and a source/drain electrode on or over the semiconductor fin, the semiconductor fin having an electrically conductive region that connects the source/drain electrode to the drift region in electrically conductive fashion, and having a limiting structure that is formed laterally next to the electrically conductive region and that extends from the source/drain electrode to the drift region, the limiting structure being set up to limit a conductive channel of the vertical field-effect transistor in the semiconductor fin to the area of the electrically conductive region.
Inventor(s): Andreas Ringk of Bamberg (DE) for robert bosch gmbh, Anton Ringel of Bamberg (DE) for robert bosch gmbh, David Thomann of Bamberg (DE) for robert bosch gmbh, Martin Gerlach of Strullendorf (DE) for robert bosch gmbh
IPC Code(s): H01M8/0221, H01M8/1004
Abstract: disclosed is a bipolar plate () for an electrochemical cell (), in particular a fuel cell. the bipolar plate () includes at least one insert () used for connection to a membrane-electrode assembly ().
20240055621.FUEL CELL STACK AND PRODUCTION METHOD_simplified_abstract_(robert bosch gmbh)
Inventor(s): Andreas Ringk of Bamberg (DE) for robert bosch gmbh, Anton Ringel of Bamberg (DE) for robert bosch gmbh
IPC Code(s): H01M8/0297, H01M8/04119, H01M8/0228
Abstract: the invention relates to a fuel cell stack () comprising at least one bipolar plate (), at least one gas diffusion layer () and at least one electrolyte, in particular at least one membrane (), wherein a coating () is arranged as a connecting means between the at least one bipolar plate () and the at least one gas diffusion layer () and the coating () is electrically conductive. the invention further relates to a method for producing the fuel cell stack ().
20240055624.FUEL CELL SYSTEM HAVING IMPROVED HUMIDIFICATION_simplified_abstract_(robert bosch gmbh)
Inventor(s): Jochen Braun of Heimsheim (DE) for robert bosch gmbh
IPC Code(s): H01M8/04119, H01M8/04082, H01M8/04492, H01M8/04746, H01M8/04828
Abstract: the invention relates to a fuel cell system, having at least one fuel cell with an anode, a cathode, a membrane arranged between the anode and the cathode, a cathode inlet, a cathode outlet, an anode inlet, and an anode outlet. according to the invention, the fuel cell system is characterized in that the fuel cell system is designed to at least partly conduct water accumulating on the anode outlet at least partially to at least one humidification connection in an oxidant line connected to the cathode inlet so that an oxidant flow flowing to the cathode inlet is humidified.
20240055629.FUEL CELL CLOSING SYSTEM_simplified_abstract_(robert bosch gmbh)
Inventor(s): Andreas Knoop of Esslingen (DE) for robert bosch gmbh
IPC Code(s): H01M8/04082
Abstract: the invention relates to a fuel cell closing valve () having a valve closing body (), which is electromagnetically movable from a first position to a second position by the energizing of an electrical coil () in order to close or open at least one medium passage of a fuel cell. in order to optimize the operation of the fuel cell system, the fuel cell closing valve () comprises two permanent magnets (), by means of which the valve closing body () can be held both in the first position and in the second position when the electrical coil () is in a currentless state.
20240055630.FUEL-CELL SYSTEM WITH PROTECTION FROM ICING_simplified_abstract_(robert bosch gmbh)
Inventor(s): Helerson Kemmer of Vaihingen (DE) for robert bosch gmbh, Jochen Braun of Heimsheim (DE) for robert bosch gmbh
IPC Code(s): H01M8/04223, H01M8/04082, H01M8/0432
Abstract: a fuel-cell system is proposed, comprising at least one fuel cell, an oxidant line, a hydrogen line, an exhaust-gas line, a control unit, and at least one electrically controllable valve, which is coupled to the control unit and is connected to one from among the oxidant line, the hydrogen line, and the exhaust-gas line. the fuel-cell system is distinguished in that the control unit is designed to activate the at least one valve in a pulsating or oscillating manner, at least during a first time interval, such that the at least one valve is prevented from remaining in a stationary state and seizing up by icing during the first time interval.
Inventor(s): Helerson Kemmer of Vaihingen (DE) for robert bosch gmbh
IPC Code(s): H01M8/04992, H01M8/04089, H01M8/04302, H01M8/0438, H01M8/0444, H01M8/04664, H01M8/04746
Abstract: the invention relates to a method for determining the length and/or volume of a purge path within a fuel cell system (), the fuel cell system () comprising a fuel cell stack (), an air path (), an exhaust line (), and a fuel line () with a recirculation loop (). during the purging process, the h concentration is measured on an h sensor () in the exhaust line () and the length and/or volume of the purge path is/are determined as a function of the profile of the measured h concentration.
Inventor(s): Michael Mahler of Leinfelden-Echterdingen (DE) for robert bosch gmbh
IPC Code(s): H02J50/70, H02J50/60, H02J50/80, H02J50/10, B60L53/122, B60L53/124
Abstract: the invention relates to a method for operating a wireless energy transmission device (), for example for charging an energy storage device () of an electric vehicle, comprising at least one transmission coil (), which is suitable for an inductive energy transmission and which comprises a transmission coil control unit (), and at least one receiving coil (), which is suitable for an energy transmission and which comprises a receiving coil control unit (). the wireless transmission device additionally comprises at least one first measuring element () and a first measuring device () which is connected to the measuring element, wherein in a first step, the field strength in an air gap () between the transmission coil () and the receiving coil () is measured by the at least one measuring device () using the measuring element (), and, in a second step, the transmission coil control unit () sets the working point of the energy transmission while taking into consideration the field strength value measured by the measuring element () such that the degree of efficiency of the energy transmission device () is maximized.
Inventor(s): Andrea MARCHINI of Kusterdingen (DE) for robert bosch gmbh, Julian Heinzelmann of Stuttgart (DE) for robert bosch gmbh
IPC Code(s): H04N5/74, G02B27/01
Abstract: a method to compensate for projection errors when outputting images using a smart-glasses system. at least one image is produced using an arithmetic logic unit of the system. the image produced or an image to be output is transmitted by the arithmetic logic unit to a micro-electromechanical output unit, particularly smart glasses, of the system. before the image is output by the output unit, a correction algorithm is executed to generate a corrected image to be output. image regions of the corrected image to be output are assigned at least one stored position within the produced image via at least one stored transformation function depending in each case on a position within the corrected image to be output. at least one image-region parameter is ascertained for the image regions to be generated depending in each case on the stored position assigned to the respective image region to be generated.
Inventor(s): Rudraksh Shrivastava of Erligheim (DE) for robert bosch gmbh, Oliver Blume of stuttgart (DE) for robert bosch gmbh, Sudeep Hegde of Stuttgart (DE) for robert bosch gmbh
IPC Code(s): H04W40/24, H04W40/22
Abstract: a method, including: transmitting, by a first terminal device, a first request to a second terminal device, via a sidelink interface, using a first sidelink communication, wherein the second terminal device is configured to serve the first terminal device as a relay terminal device, the first request indicating that a sidelink multipath operation associated with at least one further, third, terminal device should be activated for the first terminal device, and receiving, by the first terminal device, a first response to the first request from the second terminal device.
Inventor(s): Maximilian Stark of Hamburg (DE) for robert bosch gmbh, Khaled Shawky Hassan of Sarstedt (DE) for robert bosch gmbh
IPC Code(s): H04W64/00
Abstract: a computer-implemented method for transmitting information. the method includes: transmitting, by a network device, a first information to a first terminal device, the first information instructing the first terminal device to perform at least one sidelink-based positioning procedure associated with at least one further terminal device, receiving second information from at least one of a) the first terminal device and b) the at least one further terminal device, the second information characterizing at least one result of the at least one sidelink-based positioning procedure.
Inventor(s): Maximilian Stark of Hamburg (DE) for robert bosch gmbh, Khaled Shawky Hassan of Sarstedt (DE) for robert bosch gmbh
IPC Code(s): H04W64/00, H04W72/25
Abstract: a method, for example a computer-implemented method, for determining a position of a terminal device. the method includes: determining, by a network device, a position of a first terminal device, determining, by the network device, a position of a second terminal device, and initiating, by the network device, at least one sidelink-based positioning procedure associated with at least one of the first terminal device and the second terminal device.
Inventor(s): Khaled Shawky Hassan of Sarstedt (DE) for robert bosch gmbh, Sudeep Hegde of Stuttgart (DE) for robert bosch gmbh
IPC Code(s): H04W72/40
Abstract: a method for processing data associated with a terminal device configured to use at least a first radio technology, e.g. for communicating with at least one further terminal device over a sidelink interface based on the first radio technology. the method includes: determining a first parameter characterizing an activity of devices configured to use the first radio technology associated with predetermined radio resources, determining a second parameter characterizing an activity of devices configured to use at least one of a) the first radio technology, b) at least one further, e.g. second, radio technology, which is different from the first radio technology, associated with the predetermined radio resources.
Robert Bosch GmbH patent applications on February 15th, 2024
- Robert Bosch GmbH
- B24B55/10
- Robert bosch gmbh
- B60R16/03
- B60T8/1761
- B60T13/16
- B60T7/22
- B60W30/20
- B60W30/18
- B60W10/08
- B60W10/196
- B60W10/184
- B60L7/18
- B60L7/26
- B62D5/04
- B60W50/08
- B62M6/90
- B62M6/55
- B62J43/28
- B62J43/13
- F02D35/00
- F02D33/02
- F15B15/28
- F15B15/10
- F16K31/163
- F16K31/54
- G01M13/00
- G05B23/02
- G01N27/417
- G01M15/10
- G01N27/419
- F04B43/04
- G01S19/42
- G01S19/39
- G01S5/00
- H04W4/02
- H04W64/00
- H04L5/00
- G02B27/62
- H04N17/00
- G05B19/418
- G06F13/42
- G06F13/40
- G06F13/28
- G06V20/58
- G08G1/01
- H01L21/66
- H01L29/78
- H01L29/66
- H01L29/417
- H01M8/0221
- H01M8/1004
- H01M8/0297
- H01M8/04119
- H01M8/0228
- H01M8/04082
- H01M8/04492
- H01M8/04746
- H01M8/04828
- H01M8/04223
- H01M8/0432
- H01M8/04992
- H01M8/04089
- H01M8/04302
- H01M8/0438
- H01M8/0444
- H01M8/04664
- H02J50/70
- H02J50/60
- H02J50/80
- H02J50/10
- B60L53/122
- B60L53/124
- H04N5/74
- G02B27/01
- H04W40/24
- H04W40/22
- H04W72/25
- H04W72/40
