Abstract: A method for influencing light beams in the interior of a motor vehicle. The light beams come from the direction of a mirror bank associated with a head-up display. Different approaches are provided for providing an enhanced display option and simultaneously reducing a dazzling of a vehicle occupant by unwanted reflections. The light beams are generated in the mirror bank, wherein some of the generated light beams are blocked in the region of the mirror bank in such a way that a particular keep-clear region is created into which reflected light beams can no longer enter, or generated light beams in the region of the mirror bank are directed without reflection onto a particular viewing region, or the generated light beams in the region of the mirror bank are polarised and only such polarised portions of the light beams that cause no or only negligible reflections exit the mirror bank.

Abstract: A method for venting the tank of a vehicle, a device for venting the tank of a vehicle, as well as a vehicle are provided. In this context, the vehicle in which the method is employed has an internal combustion engine that can be operated with a fuel, an air supply system, an exhaust gas system comprising at least an exhaust gas turbocharger, a fuel tank that is designed to supply the internal combustion engine with fuel, and a fuel vapor sorption system. It is provided that, in the method or by means of the device, a drive flow in the air supply system is regulated as a function of an altitude reserve of the exhaust gas turbocharger and as a function of an engine load point, so that the flushing air volume flow of the tank venting system that ensues is determined and can be supplied as a function of an altitude rotational speed of the exhaust gas turbocharger and as a function of the engine load point.

Abstract: A method for determining a desired intake manifold pressure of an internal combustion engine by means of an iterative method, wherein a cylinder charge is determined for an intake manifold pressure iterated during the iterative method, and the desired intake manifold pressure is determined as a function of the cylinder air charge that has been determined. In addition, a control device for carrying out the method is provided.

Abstract: A data switching device comprises at least one interface designed to communicate with a first plurality of vehicle components of the vehicle, and to communicate with a second plurality of vehicle components of the vehicle. The data switching device includes a control circuit designed to communicate with the first plurality of vehicle components based on at least one first data format, and with the second plurality of vehicle components based on at least one second data format. The control circuit is designed to provide a communication interface for the communication between the first plurality of vehicle components and the second plurality of vehicle components. The control circuit is designed to provide access to the first data of the first plurality of vehicle components by providing second data for the second plurality of vehicle components.

Abstract: The invention relates to a method for carrying out a starting operation of a motor vehicle having a gear train that includes a dual clutch transmission with a first clutch that carries the odd-numbered gears, and a second clutch that carries the even-numbered gears, wherein the second clutch of the dual clutch transmission is used, at least in part, for preloading the gear train.

Abstract: A body structure for a vehicle has at least one side door sill that is made up of a door sill outer part on the outer side of the vehicle and a door sill inner part on the inner side of the vehicle, in the vehicle transverse direction, which delimit a door sill cavity that extends in the vehicle longitudinal direction between a front closing profile that closes off the door sill cavity in the direction of the front wheel housing, and a rear closing profile that closes off the door sill cavity in the direction of the rear wheel housing, wherein a reinforcement element, designed as an insert part, which extends in the vehicle longitudinal direction and acts as a side collision reinforcement is situated in the door sill cavity, and wherein in the event of a head-on collision the reinforcement element is acted on by a collision force directed toward the rear of the vehicle, in particular with load on at least one connecting point at which the reinforcement element is connected to the door sill.

Abstract: The present invention relates to a method, a computer program having instructions, and a device for processing signals. The invention also relates to a means of conveyance as well as an industrial machine in which a method according to the invention, or device according to the invention, is used. In a first step, the signals are sequenced into sections. Then at least one statistical feature is determined for each of the sections. Subsequently, a feature space of the determined statistical features can optionally be first transformed into a lower dimensional space. The signals are clustered based on the determined statistical features. For each cluster, a signal is then determined as a representative. At least the signals determined as representatives are finally provided for further processing. Alternatively, clusters for identifying a faulty sensor that result from clustering are used.

Abstract: The invention relates to a method for decelerating a motor vehicle at least during emergency braking, in which method a first braking torque is applied to at least one front wheel of the motor vehicle by means of at least one service brake system of the motor vehicle. According to the invention, at least one parking brake different from the at least one service brake system is activated by a control apparatus of the motor vehicle and a second braking torque is thereby applied to the at least one front wheel while the first braking torque is applied. A further aspect of the invention relates to a motor vehicle.

Abstract: In order to provide a method for de-icing a heat exchanger of a motor vehicle, which prevents large amounts of melt water from a defrosting process running onto the floor or the road beneath the motor vehicle, freeze again and pose a risk of injury to pedestrians, in a method for defrosting a heat exchanger of a motor vehicle, in which, for a heat exchanger arranged in a motor vehicle, a defrosting process for removing a layer of frozen water or frost formed on a surface of the heat exchanger is carried out, the defrosting process comprising heating the surface, and melt water being produced, it is proposed that the amount of melt water discharged onto a local region of a floor beneath the motor vehicle is limited to a maximum value.

Abstract: A method for determining a combination of an actual intake camshaft phase position of an intake camshaft and an actual exhaust camshaft phase position of an exhaust camshaft of a production internal combustion engine having at least one cylinder, wherein the method is performed in operation of the production internal combustion engine and the relevant actual phase position of the camshafts is determined in relation to an operating point of the production internal combustion engine.

Abstract: In a method for manufacturing an electric motor comprising a rotor and a stator a placeholder for a temperature sensor is inserted in the axial direction between a first coil layer and an adjacent second coil layer of a winding head such that the placeholder is situated in a gap-shaped recess extending between the first and the second coil layers, the first coil layer is then pressed onto a circumferential surface of the placeholder and onto the second coil layer and is plastically deformed such that a space between the lateral surfaces of the two coil layers and the circumferential surface of the placeholder is reduced, and a contact surface between the lateral surface of the first coil layer and the circumferential surface of the placeholder is enlarged. By removing the placeholder, a receiving chamber is subsequently formed in the winding head, into which a temperature sensor is then inserted.

Abstract: An exhaust gas aftertreatment system for an internal combustion engine charged by an exhaust gas turbocharger and spark-ignited by means of spark plugs has a particulate filter and a first three-way catalytic converter downstream from the particulate filter in a position close to the engine in an exhaust gas system connected to an outlet of the internal combustion engine and another three-way catalytic converter arranged in the underbody position of the motor vehicle, downstream from the first three-way catalytic converter. An exhaust gas burner is active from the start of the engine, introducing hot exhaust gas into the exhaust gas system downstream from the particulate filter, in order to heat at least one of the three-way catalytic converts to a light-off temperature, as quickly as possible after the cold start, thereby allowing an efficient exhaust gas aftertreatment.

Abstract: A vehicle device system for a motor vehicle, having at least one vehicle device, in particular a vehicle seat or vehicle table, and comprising a mount fastened or fastenable to a vehicle body for detachably locking the vehicle device to the vehicle body, and comprising a key-operated switch, which establishes or interrupts at least one electrical contact between the vehicle device and the vehicle depending on its switching position. It is provided that the key-operated switch is fastened on the vehicle device, which is longitudinally displaceably mounted/mountable on the mount, and interacts with a contact carriage, which is longitudinally displaceably mounted on the mount.

Abstract: A seat belt device for a vehicle seat, having a seat belt, the belt tongue of which in an engaged state is releasably connected to a seat-side belt buckle. The belt buckle is guided via at least one wire rope through a sleeve-like deflection element, which defines the course of the wire rope between its connection point on the seat side and its connection point on the belt buckle side. The sleeve-like deflection element has a predetermined deformation point, at which the deflection element is deformed in the event of a head-on collision, more specifically with the belt buckle being displaced from its use position into a crash position in which the tilt or twist moments acting on the belt buckle are reduced.