A vehicle suspension system may include hydraulic actuators, first and second conduits, and first and second switch valves. Each actuator includes a cylinder and a piston that divides an interior of the cylinder into compression and rebound chambers. First and third ports of each cylinder are openings to the rebound chamber. Second and fourth ports of each cylinder are openings to the compression chamber. The first conduit connects the third port of a first actuator with the fourth port of a second actuator. The second conduit fluidly connects the third port of the second actuator with the fourth port of the first actuator. The first switch valve is connected to the first and second ports of the first one of the hydraulic actuators. The second switch valve is connected to the first and second ports of the second one of the hydraulic actuators.

A vehicle suspension system may include hydraulic actuators, first and second conduits, and first and second switch valves. Each actuator includes a cylinder and a piston that divides an interior of the cylinder into compression and rebound chambers. First and third ports of each cylinder are openings to the rebound chamber. Second and fourth ports of each cylinder are openings to the compression chamber. The first conduit connects the third port of a first actuator with the fourth port of a second actuator. The second conduit fluidly connects the third port of the second actuator with the fourth port of the first actuator. The first switch valve is connected to the first and second ports of the first one of the hydraulic actuators. The second switch valve is connected to the first and second ports of the second one of the hydraulic actuators.

An engine coolant temperature at an expected time of activation of a vehicle is predicted. Upon determining that the predicted engine coolant temperature is greater than an ambient air temperature by a temperature threshold, a vehicle component is actuated at a time determined based on the expected time of activation.

A hydraulic suspension system controller connected with a hydraulic system of a vehicle. The controller includes a display, an indicator and buttons corresponding to functions of the controller. Each function is associated with the hydraulic system for raising and lowering solenoids connected to a hydraulic actuator to extend or contract the hydraulic actuator. A fail-safe module is connected to the controller to receive signals from a sensor array to monitor the hydraulic system.

A ground movement system for a land transport vehicle (2) capable of levitating, the vehicle having a plurality of wheels including at least one actuated wheel (3), a drive device (6) for driving the actuated wheel and/or a brake (8) for braking the actuated wheel (3), a vertical positioning actuator (9) arranged to move the actuated wheel (3) vertically relative to a fuselage of the vehicle (2), and control means arranged to act, during an acceleration stage and/or during a braking stage of the vehicle, to control the vertical positioning actuator (9) as to adjust the vertical position of the actuated wheel in order to increase the load carried by the actuated wheel and thus increase the maximum force that can be transmitted to the ground by the actuated wheel so as to increase the maximum drive and/or braking torque that can be produced by the drive device (6) and/or by the brake (8) without the actuated wheel (3) skidding or slipping.

Systems and methods for stabilizing a vehicle during a traction control event are disclosed. Signals indicative of wheel speed and velocity of the vehicle may be received at a controller of the vehicle and compared to determine wheel slip. Based on the wheel slip, the controller determines whether a burnout condition exists. A damping force of at least one damper associated with a suspension of the vehicle may be adjusted when a burnout condition is detected.

A vehicle-height adjusting system includes: vehicle-height adjusting actuators each for adjusting a vehicle height for a corresponding one of wheels; a pressure medium supplier for supplying a pressure medium from a tank to each of the vehicle-height adjusting actuators; and a vehicle height adjuster for adjusting the vehicle height for each wheel. The vehicle-height adjusting actuators include a left vehicle-height adjusting actuator and a right vehicle-height adjusting actuator. The vehicle height adjuster includes a supply amount controller configured to control the pressure medium supplier such that substantially the same amount of the pressure medium is to be supplied from the tank to the left vehicle-height adjusting actuator and the right vehicle-height adjusting actuator, when at least one of the wheels is in contact with an uneven road surface.

A vehicle-height adjusting system includes: vehicle-height adjusting actuators each for adjusting a vehicle height for a corresponding one of wheels; a pressure medium supplier for supplying a pressure medium from a tank to each of the vehicle-height adjusting actuators; and a vehicle height adjuster for adjusting the vehicle height for each wheel. The vehicle-height adjusting actuators include a left vehicle-height adjusting actuator and a right vehicle-height adjusting actuator. The vehicle height adjuster includes a supply amount controller configured to control the pressure medium supplier such that substantially the same amount of the pressure medium is to be supplied from the tank to the left vehicle-height adjusting actuator and the right vehicle-height adjusting actuator, when at least one of the wheels is in contact with an uneven road surface.

In some examples, a system receives data relating to an environment of a vehicle. Based on the received data, the system initiates a vehicle preparation action by actuating an adjustable component of the vehicle, the vehicle preparation action to ready the vehicle for a user prior to operation of the vehicle.

A computer system for performing an axle load adjustment action of vehicle axle of a vehicle is provided. The computer system including processing circuitry is configured to obtain tire data, and obtain at least one adjustment parameter, wherein at least one adjustment parameter is requirement data pertaining to the weight of the vehicle, axle load requirements of the vehicle, and the legal requirements for the road on which the vehicle is or will be travelling, determine an axle load adjustment action based on at least one adjustment parameter and based on tire data, and execute said axle load adjustment action, wherein the axle load adjustment action includes an temporarily increase of the load of the at least one axle of the vehicle.