Disclosed in the present invention are an inertial regulation method of active suspensions based on terrain ahead of a vehicle and a control system thereof. According to the scanned terrain ahead of the vehicle, a center of mass trajectory and attitude history are calculated when the vehicle passes through the terrain ahead of the vehicle with passive suspensions. After smoothing the trajectory, the active suspension is controlled to make the vehicle drives according to the smoothed trajectory. During this period, a smoothness coefficient is adjusted to make each suspension stroke be limited within a limit stroke, and according to the supporting force and stroke of each active suspension calculated from a dynamics model, the impedance control based on force-displacement is carried out on an actuator of the suspension. The present invention can significantly improve the driving comfort and handling stability of the vehicle driving on an uneven road surface.

A road surface detection system, in one example the system includes a hydraulic unit of an anti-lock braking system, the hydraulic unit including a preload adjuster, and a plurality of pressure sensors configured to generate pressure sensor data. The system also includes a controller configured to receive the pressure sensor data from the plurality of pressure sensors, determine a target preload pressure level, compare the pressure sensor data with the target preload pressure level to calculate a pressure differential between the pressure sensor data and the target preload pressure level, determine a road surface based upon the calculated pressure differential, and regulate the preload adjuster to change the pressure within the hydraulic unit based upon the road surface.

Systems and methods are provided for adjusting a control of a vehicle system based on a condition of an occupant. The system includes a replaceable or upgradeable electronic skin removably coupled to an interior vehicle component. The electronic skin includes at least one sensor positioned therein, configured to monitor/obtain a biometric, physiological, or wellness condition measurement from an occupant. The system includes one or more processors and a memory communicably coupled thereto. An occupant comfort module is provided including instructions that, when executed, collect and monitor feedback from the at least one sensor; determine that the feedback exceeds a predetermined threshold; and determine an adjustment for a vehicle system based on the feedback. A control module may be provided including instructions that, when executed by the one or more processors, cause the vehicle system to change at least one setting based on the adjustment determined by the occupant comfort module.

A suspension element includes a housing, a first joint, and a second joint. The housing is configured to couple a tractive element assembly to a vehicle. The housing has a first end configured to engage a portion of the vehicle and a second end configured to interface with the tractive element assembly. The first joint includes a first actuator and a first resilient member. The first actuator is configured to facilitate linear extension and retraction of the suspension element. The second joint includes a second actuator and a second resilient member. The second actuator is configured to facilitate rotational movement of the suspension element. The first resilient member and the second resilient member are configured to support a static load of the vehicle.

The present disclosure provides a road information correction method, apparatus, and system based on vehicle-to-everything (V2X). The method includes: sending a road information map to a first vehicle, such that the first vehicle obtains first original road information by using the road information map, and collects real-time road information; receiving the real-time road information uploaded by the first vehicle; determining, according to the real-time road information, whether the stored first original road information needs to be corrected; and if yes, correcting the stored first original road information according to the real-time road information; otherwise, not correcting the stored first original road information. According to the embodiments of the present disclosure, road information stored in a cloud can be corrected in a timely manner, and fast-changing information and slow-changing information can be identified to provide different determining mechanisms for the two, thereby ensuring precision of correcting road information.

A vehicle with a road surface condition detector includes: a vehicle body configured to have one or more passengers; front and rear wheels configured to move the vehicle body; and a road surface condition detector configured to detect road surface conditions in front of the front and rear wheels, wherein the road surface condition detector includes front-wheel road surface condition detectors configured to detect road surface conditions in front of the front wheels and rear-wheel road surface condition detectors configured to detect road surface conditions in front of the rear wheels, and the rear-wheel road surface condition detectors detect areas located outer in a vehicle width direction than ends of detection areas detected by the front-wheel road surface condition detectors.

Methods and systems for vehicle localization are provided herein. An example method can include obtaining a map within an operating area. A location within the operating area is associated with a pattern of speed bumps that is configured to produce a vehicle pitch response from the vehicle when the vehicle travels over the pattern of speed bumps. The method can include obtaining motion sensor information from a vehicle sensor, determining when the motion sensor information matches the vehicle pitch response, and determining that the vehicle is in the location when the motion sensor information corresponds to the vehicle pitch response of the location.

Disclosed herein are a damper control system and method according to rough road determination in which the number of sensors is reduced and a state of a road surface is subdivided and determined by a 6D sensor since an existing wheel G sensor is not used at the time of determining the state of the road surface.

The invention relates to a method for operating a motor vehicle, which has a contactless head-up display, kHUD, which is designed to display virtual contents in superposition with real objects, and furthermore has a semi-active damper system, which is designed to be operated selectively with one of a plurality of damper characteristic curves. In the method according to the invention, a real object located in the direction of travel of the motor vehicle is identified, and virtual content for augmenting the identified real object is determined. In order to prepare for the display of the virtual content, one of the plurality of damper characteristic curves of the semi-active damper system is then selected in order, for example, to optimize both the operation and simulation of the damper system. The virtual content is then displayed, by means of the kHUD, in superposition with the real object, with fewer spatial discrepancies.

An electrically powered suspension system includes: an actuator that generates a load for damping vibration of the vehicle body; an information acquisition part that acquires information on a sprung state amount and a road surface state; a target load calculation part that calculates a first target load related to skyhook control based on the sprung state amount and calculates a second target load related to preview control based on the road surface state; and a load control part. The target load calculation part is further configured to calculate a third target load related to virtual spring force control based on a stroke position and to calculate a combined target load into which the first target load, the second target load, and the third target load have been combined. The load control part performs load control of the actuator using the combined target load.