A suspension control system includes: a first electric current setting unit configured to set a first electric current based on an actual damping speed; a second electric current setting unit configured to set a second electric current based on a model damping speed; a weight coefficient setting unit configured to set a weight coefficient based on the actual damping speed; and a target electric current setting unit configured to set a sum of a first value and a second value as a target electric current of the damper, the first value being obtained by multiplying the second electric current by the weight coefficient, the second value being obtained by multiplying the first electric current by a value obtained by subtracting the weight coefficient from one. The first electric current setting unit is configured to make the first electric current smaller than the second electric current in a prescribed case.

Described herein are methods and systems for estimating the current weight of commercial vehicles. A system comprising a weight estimator, which receives input from one or more vehicle systems and/or sensors, such as suspension, power train, speedometer, tire pressure monitoring system, and the like. The weight estimator uses these inputs to determine one or more weight values associated with the vehicle, such as the total vehicle weight, weight distribution per axle, weight distribution per wheel, load distribution, and the like. In some examples, the weight estimator submits these weight values to one or more other systems. For example, the weight values may be used as an indicator that the vehicle is overloaded and/or that the weight is distributed unevenly. In some examples, the weight values are used by a maintenance scheduler to determine the next required maintenance.

Disclosed is a vehicle control method which comprises the steps of: determining whether or not a squat of a rear end of a vehicle body is equal to or greater than a given level; determining whether or not turning manipulation of a steering device has been made; and, when the turning manipulation of the steering device is determined to have been made, controlling each part of an engine (4) to reduce an output torque of the engine (4), wherein, in response to the determination that the turning manipulation of the steering device has been made, a reduction amount of the output torque of the engine is increased when the squat of the rear end of the vehicle body is equal to or greater than the given level, as compared to when the squat is less than the given level.

A drive control apparatus is applied to a drive system that is mounted to a vehicle, drives wheels of the vehicle by a motor, and brakes the wheels by a brake apparatus. The drive control apparatus determines a road-surface state of a travel road of the vehicle. The drive control apparatus suppresses slipping of the vehicle by correcting a drive torque by correcting at least either of a motor torque and a brake torque. When determined that the drive torque is to be corrected, the drive control apparatus adjusts a correction amount of the drive torque by adjusting the motor torque with higher priority than the brake torque in response to be determined that the road-surface state is rough.

A method for operating a vehicle hazardous parking warning system for warning a user of a first vehicle about hazardous parking of the first vehicle. The method includes detecting that the first vehicle enters a parking state at a parking position along the roadside; determining whether the parking position of the first vehicle is hazardous in terms of risk that the parked first vehicle being hit by a second, rear-coming, vehicle by retrieving stored forwards visibility information that was registered by a forwards directed sensor unit of the first vehicle while travelling of the first vehicle before entering the parking state; calculating a level of a risk parameter reflecting a risk for the parked first vehicle being hit by the second vehicle, based on the forwards visibility information; and determining that the parking position is a hazardous parking position when the risk parameter exceeds a threshold value.

The present disclosure relates to a mobility device having an active suspension function and method therefor. The mobility device may include: a suspension module located between a wheel and a sash of the mobility device and configured to perform a suspension function to the mobility device; a sensor module comprising an inclinometer and a ride height sensor; and a communication module configured to support vehicle-to-everything (V2X) communication. The communication module may be configured to provide, as first suspension module control information for a subsequent mobility device, road surface information obtained by the inclinometer and the ride height sensor during driving of the mobility device based on the V2X communication.

Provided is a driving support apparatus including: a surrounding sensor configured to acquire surrounding information on another vehicle present in front of a vehicle and dividing lines extending in front of the vehicle; and a control unit configured to: execute adaptive cruise control (ACC) of, when a preceding vehicle is determined to be present based on the surrounding information, executing acceleration control and deceleration control such that an inter-vehicle distance to the preceding vehicle matches a predetermined target inter-vehicle distance which becomes longer as a vehicle speed increases; and lengthen, when the ACC is started or the ACC is being executed in a case in which a vehicle height is increased to be higher than the normal height by vehicle height adjustment, a target-inter-vehicle-distance-when-stopped, which is the target inter-vehicle distance of when the vehicle is stopped, as compared with a case in which the vehicle height is the normal height.

A method to control, while driving along a curve, a road vehicle with a variable stiffness and with rear steering wheels. The method comprises the steps of: determining an actual attitude angle of the road vehicle; establishing a desired attitude angle; determining an actual yaw rate of the road vehicle; establishing a desired yaw rate; and changing, in a simultaneous and coordinated manner, the steering angle of the rear wheels and the distribution of the stiffness of the connection of the four wheels to the frame depending on a difference between the actual attitude angle and the desired attitude angle and depending on a difference between the actual yaw rate and the desired yaw rate.

A method for determining the payload mass resting on a wheel of a vehicle. In the method: using a level sensor system, in a time period in which the vehicle is moved, a time series of measured values is detected, which each indicate the vertical position of the vehicle body in relation to the wheel; a model is provided for the temporal development of the vertical position under the influence of the gravitational force of vehicle body and payload, an elastic suspension between the vehicle body and the wheel of the vehicle, and a damping of the vertical relative movement between the vehicle body and the wheel of the vehicle, the model being parameterized at least using the sought payload mass and the wheel of the vehicle and the connection of the wheel to the roadway being assumed to be rigid.

The disclosed invention makes use of slip related values to calculate friction related values and tire stiffness related values and feeds back an estimated tire stiffness relates value or a calculated friction related as a basis for further calculations. In particular, the disclosure relates to methods, apparatuses and computer program products to achieve the mentioned objective.