The present invention relates to a method for determining a desired speed of a vehicle (1), preferably an autonomous vehicle. The vehicle comprises a shock absorber arrangement (2), preferably an hydraulic shock absorber arrangement, having an elastic hysteresis. The method comprises—obtaining (501) a reference value indicative of the energy dissipated by the shock absorber arrangement (2) in a reference driving condition of a vehicle and—determining (502) a speed of the vehicle for which the value indicative of the energy dissipated by the shock absorber arrangement (2) in a similar driving condition is expected to fall within a predetermined energy dissipation range, using said reference value.

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.

The present invention relates to a method for determining a desired speed of a vehicle (1), preferably an autonomous vehicle. The vehicle comprises a shock absorber arrangement (2), preferably an hydraulic shock absorber arrangement, having an elastic hysteresis. The method comprisesobtaining (501) a reference value indicative of the energy dissipated by the shock absorber arrangement (2) in a reference driving condition of a vehicle anddetermining (502) a speed of the vehicle for which the value indicative of the energy dissipated by the shock absorber arrangement (2) in a similar driving condition is expected to fall within a predetermined energy dissipation range, using said reference value.

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.

An approach to setting a cruise control speed based on identifying a vehicle operator and analyzing metadata associated with the vehicle operator. The identity of the vehicle operator and any passengers is determined based on identity sensors in the vehicle or by manual identity entry. Metadata, associated with the vehicle operator, is retrieved from the metadata database, located either locally or remotely. The metadata is analyzed based on factors such as the current route and the identity of any passengers. The cruise control speed is set based on the results of the analysis. Any changes to the setting are updated in the metadata database.

A wheel based vehicle configured to travel along a roadway environment, the wheel based vehicle comprising: a first independent suspension element, a second independent suspension element, at least one electromagnetic sensing device, and processing circuitry. The first independent suspension element is configured to service a first wheel with a first suspension performance. The second independent suspension element configured to service a second wheel with a second suspension performance. The at least one electromagnetic sensing device is disposed and configured to capture image data of the roadway environment. The processing circuitry is configured to: identify, based on the captured image data and vehicle motion data, first future predictions of first drive situations to be accommodated, and second future predictions of second drive situations to be avoided; and accommodate the first future drive situations by selection of a third suspension performance for the first independent suspension element.

A lookahead vehicle suspension system comprises a first independently adjustable suspension system associated with a front wheel; a second independently adjustable suspension system associated with a rear wheel; at least one detector configured to at least assist in delivering electrical signals relating to a front wheel roadway concern, the front wheel roadway concern relating to a roadway defect; and processing circuitry. The processing circuitry is configured to receive, in advance of the rear wheel encountering the roadway defect, both vehicle motion data and the electrical signals, and identify, based on the vehicle motion data and the electrical signals, adjustments with associated timing to be made to the second independently adjustable suspension system to accommodate the encounter of the rear wheel with the roadway defect.

A cooperative control module, an adaptive cruise system and a control method thereof, and a vehicle are provided. The adaptive cruise system comprises a vehicle sensor module, a driving environment intelligent sensing module, a vehicle state response estimation module, an adaptive cruise and controllable suspension cooperative control module, and a power control module. The control method of adaptive cruise is optional, one is according to the cruise speed set by the driver, and the other one is according to the cruise comfort set by the driver. In the case of adaptive cruising according to cruise comfort, the optimal cruise speed is intelligently calculated by the adaptive cruise and controllable suspension system based on driving conditions and driver's demands. The controllable suspension is controlled cooperatively during cruising, and the suspension control parameters are adaptively switched according to the performance requirements of the vehicle under different driving conditions.

A vehicle configured to move along a roadway that has an upcoming roadway concern located in front of a front wheel of the vehicle, the vehicle comprising: an independently adjustable suspension system; at least one capture element configured to capture image data corresponding to the upcoming roadway concern; and processing circuitry. The processing circuitry is configured to determine, based on current drive control function settings, and the captured image data and vehicle motion data: whether to automatically adjust the independently adjustable suspension system to accommodate an encounter with the upcoming roadway concern, whether to deliver for the driver an indication associated with the upcoming roadway concern, and whether to automatically modify at least one of the current drive control function settings to avoid the upcoming roadway concern.

A lookahead vehicle suspension system comprises a first independently adjustable suspension system associated with a front wheel; a second independently adjustable suspension system associated with a rear wheel; at least one detector configured to at least assist in delivering electrical signals relating to a front wheel roadway concern, the front wheel roadway concern relating to a roadway defect; and processing circuitry. The processing circuitry is configured to receive, in advance of the rear wheel encountering the roadway defect, both vehicle motion data and the electrical signals, and identify, based on the vehicle motion data and the electrical signals, adjustments with associated timing to be made to the second independently adjustable suspension system to accommodate the encounter of the rear wheel with the roadway defect.