A vehicle motion control method controls a motion state of a vehicle during a vehicle transient motion in which an acceleration in a lateral direction is generated in the vehicle. The vehicle motion control method includes: setting a corrected longitudinal acceleration for correcting a basic longitudinal acceleration determined in accordance with a required driving force for traveling of the vehicle; and determining a target longitudinal acceleration from the basic longitudinal acceleration and the corrected longitudinal acceleration, and operating a traveling actuator of the vehicle based on the target longitudinal acceleration. A direction and a magnitude of the corrected longitudinal acceleration are determined from a viewpoint of suppressing a change in a posture of an occupant of the vehicle in a roll direction.

The invention concerns a method and a system for recognizing the presence of any irregularities of any road pavement.

A method to determine a roll angle (λ.sub.E) of a vehicle, wherein the roll angle (λ.sub.E) is calculated as a combination of at least a first roll angle variable (λ.sub.1) and a second roll angle variable (λ.sub.2), wherein the first roll angle variable (λ.sub.1) is determined from an acquired rolling rate ({dot over (λ)}.sub.m) of the vehicle using a first method, wherein the second roll angle variable (λ.sub.2) is determined from one or more further vehicle movement dynamics characteristic variables using a second method.

A control system for reducing drive shaft vibration of an environment-friendly vehicle includes: a drive shaft speed extraction unit that extracts an actual drive shaft speed of a motor and extracts a drive shaft speed from which a forced vibration component that is to be transferred by an engine to the drive shaft is removed; a model speed computation unit that calculates a model speed of the drive shaft; a free vibration computation unit that computes a free vibration component on the basis of deviation between the drive shaft speed and the calculated model speed; and a first torque computation unit that calculates, from the free vibration component, a free vibration reduction compensation torque for reducing the drive shaft vibration.

An apparatus may include a driving information input unit for receiving driving information generated while a vehicle travels, a steering angle location control unit for receiving a command steering angle for autonomous driving and a current motor steering angle of a driving motor and outputting an autonomous driving command through location control, and a motor-driven power steering control unit for driving the driving motor based on the autonomous driving command in an autonomous driving mode, determining whether a driver intervenes in steering, based on the driving information during the autonomous driving, computing a driver command according to the driver' steering based on a result of the determination, computing a compensation output between the autonomous driving command and the driver command by applying a weighting according to a steering angular speed, and making a mode transition from the autonomous driving mode to a driver mode while driving the driving motor.

A rut determination device is configured to determine, for each road section, presence or absence of a rut based on any one of a plurality of first variation quantities each of which is the variation quantity of a vehicle-body slip angular velocity per unit time for each vehicle, a plurality of first processed values each of which is a value obtained by performing predetermined processing for each of the plurality of the first variation quantities, a plurality of second variation quantities each of which is the variation quantity of a vehicle-body slip-related value, which is the product of the vehicle-body slip angular velocity and the vehicle speed for each vehicle, per unit time, and a plurality of second processed values each of which is a value obtained by performing the predetermined processing for each of the plurality of the second variation quantities.

A steering control apparatus includes: a command steering angle acceleration detector configured to detect a command steering angle acceleration, in an autonomous driving mode, using a command steering angle inputted from an autonomous driving system; an autonomous driving determiner configured to determine whether to cancel the autonomous driving mode using any one or any combination of any two or more of a column torque of a steering shaft, a vehicle speed of a vehicle, and the command steering angle acceleration; and a steering angle controller configured to control a steering angle, in the autonomous driving mode, by adjusting a gain according to a steering angle error between the command steering angle and a current steering angle, based on an output from the command steering angle acceleration detector.

A fail-safe interface for a by-wire vehicle control system merges driver commands and external commands developed by a by-wire control unit to form a failure-tolerant actuator command that never diminishes a driver command. External commands are passed through a fault detection circuit that filters out aberrant cyclical and constant command signals from the by-wire control unit, and the actuator command is determined according to the higher or maximum of the driver-generated and external commands. The interface is powered by vehicle power supply, and is electro-optically isolated from the external control unit so that if the external control unit loses power, the actuator command faithfully follows the driver command.

A control system for reducing drive shaft vibration of an environment-friendly vehicle includes: a drive shaft speed extraction unit that extracts an actual drive shaft speed of a motor and extracts a drive shaft speed from which a forced vibration component that is to be transferred by an engine to the drive shaft is removed; a model speed computation unit that calculates a model speed of the drive shaft; a free vibration computation unit that computes a free vibration component on the basis of deviation between the drive shaft speed and the calculated model speed; and a first torque computation unit that calculates, from the free vibration component, a free vibration reduction compensation torque for reducing the drive shaft vibration.

A method of evaluating a driving skill executed by a computer includes a skill evaluation step of evaluating a driver's driving skill based on a detection value of a vehicle state, a component separating step of separating the detection value of the vehicle state into a driver's operation component reflecting a driver's motion and a non-driver's operation component without reflecting the driver's motion, and a skill evaluation modifying step of correcting or abandoning evaluation of the driving skill based on at least one of an amount of the driver's operation component and an amount of the non-driver's operation component.