A system and method for controlling a vehicle, where the system includes independent driving modules each including a connection device having a rotation center spaced apart from a driving shaft in a forward/rearward direction and configured to connect the wheel and a vehicle body to move the wheel in the forward/rearward or an upward/downward direction, a shock absorber extending in a longitudinal direction and configured to contract or stretch, to connect the vehicle body and the connection device, and to restrict an upward/downward movement of the connection device, and a driving device configured to rotate the wheel, a road surface detector configured to detect a height displacement or a state of a road, and a controller configured to control velocities of the front and rear wheels of the independent driving modules, and to change a height of the vehicle based on the height displacement or the state of the road.

An active vehicle height control method may include securing a road surface profile for unevenness of a road ahead of a vehicle and forming a target vehicle height profile by filtering the road surface profile. In addition, a controller is configured to form a disturbance profile using the road surface profile and the target vehicle height profile. The controller estimates vehicle behavior for the disturbance profile. Furthermore, the controller determines an inverse-phase control force that minimizes the estimated vehicle behavior, and drives an actuator using the inverse-phase control force to adjust a height of the vehicle.

An apparatus and method for controlling an air suspension of a vehicle are disclosed. The apparatus includes a compressor configured to supply compressed air, a reservoir configured to store compressed air supplied from the compressor and to supply the stored compressed air to the air suspension during vehicle height control, a road information provider configured to provide road state information of a road in front of the vehicle during travel of the vehicle, and a controller configured to determine a vehicle height control position of the air suspension based on the road state information and to operate the compressor before the vehicle arrives at the determined vehicle height control position, thereby filling the reservoir with the compressed air such that an internal pressure of the reservoir reaches at least a predetermined reference pressure.

The present technology is directed to identifying road surface features and underground features using a ground-penetrating radar (GPR) sensor. The present technology may include activating the GPR sensor on a vehicle to transmit a pulsed electromagnetic signal toward a ground surface. The present technology may also include receiving the pulsed electromagnetic signal reflected from the road surface features and underground features by the GPR sensor. The present technology may also include filtering the pulsed electromagnetic signal to generate a shallow-GPR data or deep-GPR data, wherein the shallow-GPR data is used to identify the road surface features and the deep-GPR is used to identify the underground features. The present technology may also include adjusting operational parameters based on at least one of the road surface features and the underground features.

In a method of creating a database for preview vibration damping control, road surface displacement-associated information detected by a detection device is acquired, positional information capable of identifying a position where the road surface displacement-associated information is detected is acquired, a road surface displacement-associated value associated with a vertical displacement of a road surface is calculated based on the road surface displacement-associated information, and a set of data obtained by linking the road surface displacement-associated value and the positional information with each other is stored into a storage device as part of a database. When it is determined that the magnitude of the road surface displacement-associated value exceeds a permissible reference value set in advance, the magnitude of the road surface displacement-associated value is corrected in a reducing manner, prior to the step of storing the set of data into the storage device.

A vehicle control method includes a step of executing preview vibration damping control for controlling a control force generating apparatus, when a wheel passes a predicated passage position, on the basis of a target control force computed by using a road surface displacement related value at the predicated passage position. The control method further includes a step of determining whether or not a predetermined condition is satisfied, the predetermined condition being satisfied when a time series change of the road surface displacement related value on a predicted route of the wheel falls within a controllable range of the control force generating apparatus, and a step of executing a particular process for reducing the magnitude of the road surface displacement related value at the predicted passage position when the predetermined condition is not satisfied.

A controller executes full extension suppression control or full compression suppression control of adjusting a damping force to be large when a piston being displaced through sliding in an inner tube approaches a full extension position or a full compression position. Moreover, a stroke from a neutral position of the piston in the inner tube to a full compression control start position is set so as to be longer than a stroke from the neutral position of the piston to a full extension control start position. A portion between the full extension control start position to the full compression control start position is set to a dead zone in which none of the full extension suppression control and the full compression suppression control are executed.

An apparatus for controlling a suspension of a vehicle includes: the electronically controlled suspension arranged between wheels and a vehicle body and configured to increase or decrease a contact force between a tire of the vehicle and a road surface; and a controller that adjusts a height of the vehicle depending on a type of road when it rains and adjusts an operating time of the suspension based on a lateral acceleration of the vehicle.

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.

A vehicle control method includes a step of executing preview vibration damping control for controlling a control force generating apparatus, when a wheel passes a predicated passage position, on the basis of a target control force computed by using a road surface displacement related value at the predicated passage position. The control method further includes a step of determining whether or not a predetermined condition is satisfied, the predetermined condition being satisfied when a time series change of the road surface displacement related value on a predicted route of the wheel falls within a controllable range of the control force generating apparatus, and a step of executing a particular process for reducing the magnitude of the road surface displacement related value at the predicted passage position when the predetermined condition is not satisfied.