A vehicle includes a body holding device configured to hold the body of a seated driver; a travel control unit configured to drive the vehicle body so that it travels; and a maximum vehicle speed setting unit configured to set a set maximum vehicle speed. The travel control unit controls an output from the driving unit based on the operation amount of an accelerator device if the vehicle speed is lower than the set maximum vehicle speed, and restricts the output from the driving unit irrespective of the operation amount of the accelerator device if the vehicle speed is equal to or higher than the set maximum vehicle speed. The maximum vehicle speed setting unit sets, if it is detected that the body holding device is worn, a first vehicle speed as the set maximum vehicle speed, and sets, if it is detected that the body holding device is not worn, a second vehicle speed lower than the first vehicle speed as the set maximum vehicle speed.

A method for controlling a personal protection device for a vehicle. The method includes a step of determining a set of control variants for controlling the personal protection device, from a plurality of possible control variants for controlling the personal protection device, using an inaccurate situational value and at least one inaccuracy value, the inaccurate situational value representing a value ascertained using a sensor of the vehicle, and the inaccuracy value defining an inaccuracy of the inaccurate situational value; and a step of selecting a control variant assigned to the inaccurate situational value, from the plurality of possible control variants, as a control variant selected for controlling the personal protection device, if each control variant of the set of control variants is assigned a safety class, which satisfies a safety criterion necessary for controlling the personal protection device.

A method for controlling a motor vehicle having an electronic control unit (ECU), includes enabling an initial set of vehicle performance limits of the motor vehicle via the ECU in response to a request signal from a computer device. The method includes detecting a current vehicle state of the motor vehicle, including one or more of a location of the motor vehicle, an occupancy state of the motor vehicle, and/or an experience level of a driver thereof, and dynamically adjusting at least one of the performance limits in response to the current vehicle state. A motor vehicle includes one or more road wheels and vehicle components connected to a vehicle body. The ECU includes non-transitory memory on which is recorded instructions for performing the method.

A method for controlling operations of safety devices of a vehicle includes determining whether there is a possibility of a collision with a preceding vehicle on the basis of vehicle driving information, determining occupancy information of a passenger or a type of a passenger or determining whether a passenger has fastened a seat belt using vehicle sensor information, and determining whether to apply, and applying accordingly, full braking, a full braking profile, or an airbag deployment scheme according to the occupancy information of a passenger, the type of the passenger, or whether the passenger has fastened a seat belt when a possibility of a collision is determined, and fully retracting the passenger's seat belt before full braking is applied after partial braking is applied.

A front airbag for vehicles including an airbag cushion may include a rear panel located at the side of a steering wheel and a front panel located at the side of a passenger and having a shape corresponding to the shape of the rear panel, the rear panel and the front panel provided with protruding supports formed at both sides of the lower end portions thereof, a first tether connecting the central part of the front panel, corresponding to a loading position of the passenger's head, to an airbag housing, and second tethers connecting the lower end portion of the front panel, corresponding to a loading position of the passenger's chest, to the airbag housing and having a shorter length than that of the first tether.

An image is received from an image sensor. The image includes an occupant's head. A seated height of the occupant is determined based at least in part on a distance from the image sensor to the occupant's head, and a detected angle of a vehicle seat. A safety device is adjusted based at least in part on the seated height of the occupant.

A method for controlling an actuatable safety device (110) for helping to protect a vehicle occupant includes sensing left-front and right-front pressure values via a pressure tube sensor (18). The method also includes executing pressure tube metrics that evaluate the left-front and right-front pressure values and selecting switched crash thresholds in response to the pressure tube metrics. The method also includes sensing vehicle acceleration parameters (99) and executing one or more crash metrics that evaluate the vehicle acceleration parameters to determine whether the switched crash thresholds are exceeded. The method further includes controlling deployment of the actuatable safety device (110) in response to determining that the switched crash thresholds are exceeded. A vehicle safety system (100) implements the method.

A method is described for operating a vehicle, including the following steps: ascertaining a collision probability for the vehicle, ascertaining an effectiveness parameter assigned to a restraint system of the vehicle, which is a measure of how effectively the restraint system may protect a vehicle occupant in the event of a collision assigned to the collision probability, and carrying out at least one injury-mitigating measure depending on the ascertained effectiveness parameter in order to mitigate an occupant injury during a collision. Also described are a corresponding device and a computer program.

A spatial position of at least one first body part, arranged within a sensing range of a sensing device of the motor vehicle, of a vehicle occupant is sensed with respect to the motor vehicle by the sensing device. An anthropometric data model is provided with data including the dimensions of predetermined body parts of a person and the positioning of the body parts with respect to one another. As a result, a spatial position of at least one second body part of the same vehicle occupant which is arranged outside the sensing range of the sensing device can be determined, taking into consideration the sensed spatial position of the first body part and the anthropometric data model. At least one functional unit of the motor vehicle is actuated taking into consideration the sensed spatial position of the second body part.

Systems, apparatus, and methods implemented in algorithms, software, firmware, logic, or circuitry may be configured to process data and sensory input in real-time to detect an object. In particular, a method may include determining a predicted object path of the object. The method may further include determining a predict point of impact between the autonomous vehicle and the object based in part on the predicted object path. The method may further include identifying a preferred point of impact that is associated with a safety system disposed on the autonomous vehicle. The method may further include causing the autonomous vehicle to perform a maneuver based in part on the preferred point of impact.