A system in a vehicle, comprising one or more physiological sensors configured to obtain stress-load data indicating a stress load of an occupant of the vehicle, a controller in communication with the one or more physiological sensors, wherein the controller is configured to determine a stress load of the occupant utilizing at least the stress-load data and output an instruction to execute a vehicle driving-dynamics features when the stress load exceeds a threshold, wherein the vehicle driving-dynamics features includes adjusting an active suspension of the vehicle.

A vehicle having a control system to utilize a movable suspension to increase sensor coverage. The control system can detect an object of interest that is partially, or completely, outside the field of view of one or more sensors on the vehicle. The system can then use the movable suspension to raise one portion of the vehicle and/or lower another portion of the vehicle to bring the object of interest at least partially into the field of view of the sensor, increasing the effective field of view of the sensor. When an object of interest is determined to be significant (e.g., a traffic or street sign), the system can attempt to bring the object of interest into view of the sensor by tilting the vehicle. The system can use different tilt rates and/or tilt angles depending on whether the vehicle is occupied or not.

In an embodiment an apparatus for controlling a height of a vehicle includes a seat having a seat unit and a backrest unit, the seat unit movable in directions of two or more axes, a control module configured to determine a position of the seat in a state in which a driver is seated, estimate a body shape of the driver based on the position of the seat, calculate a vehicle height adjustment parameter based on the body shape and generate a suspension control signal for adjusting a vehicle height based on the vehicle height adjustment parameter and a suspension driving device configured to control a suspension based on the suspension control signal.

An acceleration of a head of an occupant of a vehicle relative to the vehicle is determined based on data describing motion of the vehicle and respective poses of the head from a plurality of consecutive frames of image data. A vehicle suspension is adjusted based on the determined acceleration.

A method for performing open-loop or closed-loop control of a driver's cab mount of a motor vehicle, wherein the driver's cab mount has dampers whose damper force can be adjusted, wherein the motor vehicle can be operated in a first driving mode in which the motor vehicle automatically carries out vehicle guidance comprising both a longitudinal guidance operation and a transverse guidance operation of the motor vehicle, and in a second driving mode where the motor vehicle can be controlled by the driver, in which driving mode a driver of the motor vehicle is intended to carry out at least part of the vehicle guidance, wherein when the motor vehicle is operated in the first driving mode, the adjustable dampers of the driver's cab mount are actuated or adjusted in such a way that pitching or rolling movements are reduced compared to the second driving mode.

A ride-height adjustment system for a vehicle. The system has a first detector, to detect a preliminary end-of-journey (EOJ) event, such as seat belt unbuckling or ignition switch-off. A controller adjusts the vehicle's suspension system in a first movement in response to detection of the preliminary EOJ event, to change the ride height of the vehicle towards an access ride height of the vehicle. The access ride height is a predetermined ride height that facilitates egress from and entrance to the vehicle. A second detector detects opening of a door of the vehicle. When the ride height of the vehicle remains different from the access ride height after the first movement, the controller adjusts the suspension system in a second movement in response to the door-opening detection. This further changes the ride height of the vehicle towards the access ride height of the vehicle.

A vehicle system is described and includes a seat configured to support an occupant and to be mounted in a vehicle and a motion sickness stimuli sensing system, which can be at least partially integrated into the seat to sense parameters experienced by a seat occupant and configured to output sensed signals, e.g., motion, oscillations, physiological parameters, an electro-dermal potential signal, and the like. A controller is configured to receive the sensed signals to determine a motion sickness of the occupant. The controller can use other sensor signals in a vehicle relating to motion sickness. The controller can output a signal to start anti-motion sickness countermeasures.

The invention resides in a system and method for determining the manner in which a vehicle is driven. The system comprises a processor comprising an input configured to receive dynamic ride data from at least one on-board vehicle dynamic ride sensor, wherein the processor is configured (i) to calculate an output signal which is indicative of whether the dynamic ride data exceeds at least one dynamic ride data threshold value for a predetermined period of time; and (ii) to compare the output signal with at least one output threshold to determine the manner in which the vehicle is driven. The processor comprises an output configured to send a control signal to one or more vehicle components, wherein the control signal is indicative of the manner in which the vehicle is driven.

There are provided an apparatus and a method for controlling a variable axle for preventing a safety accident. An apparatus for controlling a variable axle that controls operation power to one switch which is short-circuited or opened according to a manipulation of a user, and supplies the operation power for a descent of a pusher axle, includes: the other switch having one end connected to power of a vehicle and the other end which is short-circuited or opened in response to a control signal, to thereby supply the power of the vehicle as the operation power at the time of the short-circuit; and a controller confirming whether or not the vehicle is remotely being started when an ignition of the vehicle is turned-on, and opening the other switch by the control signal in the case in which the vehicle is remotely being started as a result of the confirmation.

A user device is identified as being operated by a vehicle occupant. An operation being performed by the user device is identified. A road condition is determined. A vehicle suspension is adjusted based at least in part on the identified user device operation and the road condition.