Abstract: A method is described for changing a route and/or a driving style in a vehicle as a function of an interior situation. The method includes a step of identifying the interior situation in an interior space of the vehicle, and a step of outputting (510) a control command for controlling a vehicle in order to change the driving style and/or a route of the vehicle in response to the identified interior situation, and/or the outputting of an alarm signal in order to initiate an assumption of the vehicle control by the driver.

Abstract: Triggering personal protection devices for a vehicle with the aid of a sensor having a local sensor time set with respect to a common system time.

Abstract: A pre-crash seat actuator system for moving a vehicle seat includes an occupant protection control system that determines a collision is imminent and provides a trigger signal and an enable signal. A vehicle seat controller receives the trigger signal and determines a moving the vehicle seat to a desired position to mitigate severity of a collision. In response to the trigger signal, the vehicle seat controller provides a fast mode voltage for moving the vehicle seat in a fast mode. A smart control adapter determines whether the fast mode voltage and the enable signal are both received, to provide the fast mode voltage to a vehicle seat electric drive. In another embodiment, the vehicle seat controller receives the trigger signal and a collision signal to provide fast mode voltage, and the seat is returned to an original position when a crash does not occur.

Abstract: A method for operating a mobile device with a communication module and an accumulator, in particular a hand-held power tool, includes powering the communication module via electricity from the accumulator. The communication module enables wireless communication, and is powered only temporarily at least for transmitting data.

Abstract: An apparatus for ascertaining the surroundings for a vehicle includes a housing configured to receive a device for ascertaining the surroundings of the vehicle and a movement device. The movement device is connected to the housing and is coupled to a structural element of the vehicle. The movement device is configured to move the housing relative to the structural element in response to a triggering signal in order to initiate a protective function in a case of an impact effect that is acting upon the vehicle.

Abstract: The disclosure relates to a device for a vehicle. The device comprises a component for the vehicle and an explosive module. The explosive module is configured so as in response to a trigger signal to cause the component to fragment.

Abstract: A device and method for triggering an automatic response of a motor vehicle to an imminent accident situation by using data in a processing unit to create a traffic situation model of the existing traffic situation, analyzing a traffic situation and ascertaining response options, determining sequences to be expected beyond the primary accident incorporating subsequent movements of the road users and objects involved leading to secondary accidents or further subsequent accidents or potentially arising further hazardous situations, computing a probability distribution and/or an extent of injuries to persons and/or damage to objects of the road users and objects involved as a function of the response options, selecting that response option that is expected to have the smallest total degree of probability or the smallest extent of injury to persons and/or damage to objects overall for all road users and objects, and outputting control signals to initiate the selected response option.

Abstract: A method for controlling an occupant protection system of a vehicle includes reading in at least one vehicle acceleration value representing an acceleration of the vehicle and at least one model parameter of an occupant model by which a vehicle occupant is represented by at least two, in particular three, mass points. The vehicle acceleration value and the model parameter are processed in order to determine at least one motion parameter relating to the two, in particular three, mass points. Using the motion parameter, a control signal for controlling the occupant protection system is produced.

Abstract: A pre-crash system has at least one dummy actuator and an adaptive pre-trigger function that is implemented with different parameter sets as a function of a current degree of validation, and evaluates the acquired physical quantities for pre-crash recognition in order to recognize an unavoidable crash, a first parameter set, which limits the pre-trigger function to a dummy operating mode in which the pre-trigger function produces at least one trigger signal for the dummy actuator if the evaluation of the physical quantities permits the inference of an unavoidable crash, being implemented until the current degree of validation satisfies a specified condition, the pre-trigger function comparing the triggering of the dummy actuator with the behavior of the evaluation and control unit, and, as a function of the comparison, rating the triggering of the dummy actuator as “correct” or as a “false positive.

Abstract: A method for identifying the type and/or the severity of a collision of a vehicle of a first mass with a collision object of a second mass in an early phase to trigger safety measures, including: detecting surroundings data of the vehicle; identifying the collision object from the surroundings data; extracting a reference feature, not lying in a direct collision area, of the collision object; repeated successive ascertainment of an instantaneous speed of the vehicle and determining a change of the speed of the vehicle; repeated successive determination of an instantaneous relative speed between the vehicle and the reference feature and determining a change of the speed of the collision object; estimating a mass ratio, effective during the collision, between the mass of the vehicle and the mass of the collision object from the ascertained changes of the speeds of the vehicle and of the collision object.

Abstract: A method for providing a piece of occupant information for a safety unit for a vehicle includes reading in image data representing an occupant of the vehicle via an interface to an image recording unit of the vehicle, reading in plausibility check data representing a person via an interface to a mobile device, a step of determining occupant data characterizing the occupant using the image data and the plausibility check data, and a step of providing the occupant data to an interface to the safety unit for the vehicle.

Abstract: A method for activating a passenger protection device of a vehicle. A relative velocity value, which represents a relative velocity between the vehicle and an object, and at least one correction value are read in. In a further step, a velocity reduction value, which represents a decrease of a velocity of the vehicle when the vehicle collides with the object, is ascertained using the relative velocity value and the correction value. Finally, an activation signal for activating the passenger protection device is generated using the velocity reduction value.

Abstract: A pre-collision system for an occupant protection system of a vehicle, includes a predictive sensor system, a vehicle seat, a restraint system, and an evaluation and control unit that evaluates output signals of the predictive sensor system and activates a belt tensioning function of the restraint system if the evaluation of the output signals indicates an imminent collision, where the belt tensioning function generates a tensile force in the belt, which presses a corresponding occupant into the vehicle seat, with a resulting kinetic energy of the occupant that releases a pre-trigger mechanism, which is integrated into a mounting of the vehicle seat, and that enables a blocked degree of freedom of the vehicle seat so that the entire vehicle seat tilts about a defined tilt axis in the direction of an expected impact force.

Abstract: A method for actuating restraint means for a vehicle, the method having the following steps: detecting, at a first instant, at least one first value that represents an acceleration; ascertaining a value that represents a force acting on the vehicle from the detected at least one first value that is representative of an acceleration; actuating the restraint means as a function of the ascertained value and/or a value that is derived from the ascertained value.

Abstract: An identification module for mobile objects, in particular hand-held power tools, includes a housing, a transponder, and a stored energy source. The housing has a mechanism configured to arrange and/or fasten the identification module to a mobile device. The transponder has a data memory and a radio module. The memory is configured to store identification data, and the radio module is configured to send the identification data. The stored energy source is configured to power the transponder. The housing has a chamber, an opening into the chamber, and a lid configured to close the opening. The opening is configured so as to enable the stored energy source to be removably arranged in the chamber via the opening.

Abstract: A method for adapting a driving behavior of a semi, highly or fully automated vehicle and includes the following steps: receiving passenger compartment data; ascertaining a safety state of at least one vehicle occupant which in particular represents an injury probability of the vehicle occupant in the event of an accident, based on the passenger compartment data; and adapting the driving behavior of the vehicle based on the safety state of the at least one vehicle occupant.

Abstract: A method for the assisted emergency braking of a vehicle, in which the lateral and/or the longitudinal guidance of the vehicle are/is influenced in such a way that the vehicle is guided in the direction of a safety zone, and when the safety zone has been reached, a parking position, in particular within the safety zone, is ascertained for the vehicle, the vehicle being guided in such a way that the vehicle comes to a standstill in the parking position.

Abstract: A method for a vehicle, by which it is determined whether a further vehicle located in the surroundings of the vehicle is operated in an at least semi-automated manner. The method includes detecting at least one parameter of the further vehicle and determining, on the basis of the at least one parameter, whether the further vehicle is operated in an at least semi-automated manner.

Abstract: A method for setting an activation signal for activating at least one safety device of a vehicle. The method includes reading in a driving mode signal. In this case, the driving mode signal represents an item of information as to whether a manual driving mode or an at least partially automatic driving mode of the vehicle is set. The method also includes adapting at least one parameter of the activation signal while using the driving mode signal, to set the activation signal.

Abstract: The invention relates to a method for changing a forward displacement (104) of an occupant (106) of a vehicle (100) during braking of the vehicle (100). Initially, a seat belt status signal (112) which represents a status of a seat belt (108) for buckling in the occupant (106), and an occupant position signal which represents a position and/or location of the occupant (106) in the vehicle (100) and/or a change in the position and/or the location are read in. The two signals are processed to ascertain the forward displacement (104). Finally, at least one control signal (120, 121, 138) for controlling a braking device (122) of the vehicle (100) and/or at least one restraint means (108, 132) for restraining the occupant (106) is/are generated as a function of the forward displacement (104) in order to alter the forward displacement (104).