An embodiment of the present invention provides higher ride comfort to a driver in control of steering and suspension. An ECU (600) includes: a steering control section (610) which controls a magnitude of an assist torque or a reaction torque; and a suspension control section (650) which controls a damping force of a suspension. The steering control section (610) refers to a state of a vehicle which state is predicted by the suspension control section (650), and the suspension control section (650) refers to a steering torque.

A parking assistance system is provided for a motor vehicle for automated pulling-out with at least automated lateral control out of a longitudinal parking space. The automated pulling-out process comprises a plurality of pulling-out moves. The parking assistance system is designed to carry out, in an automated manner, a substantially linear reversing move as the last move of the automated pulling-out process before transferring control to the driver. The parking assistance system subsequently transfers control to the driver.

An operating system for an automated vehicle includes a failure-detector and a controller. The failure-detector detects a component-failure on a host-vehicle. Examples of the component-failure include a flat-tire and engine trouble that reduces engine-power. The controller operates the host-vehicle based on a dynamic-model. The dynamic-model is varied based on the component-failure detected by the failure-detector.

A control device includes an electronic control unit configured to expand a first detection range at least in front of a host vehicle during execution of current first steering control, determine whether next first steering control is needed to be implemented and whether a relative direction of a next second object with respect to the host vehicle is the same as a relative direction of a first object with respect to the host vehicle when the second object is detected, and perform relaxation steering control based on a target value smaller in absolute value than a return target value after an end of the current first steering control when the implementation of the next first steering control is determined to be needed and the relative directions with respect to the host vehicle are determined to be the same between the second and the first object.

A vehicle control apparatus according to the present invention outputs a signal regarding a target braking/driving force for guiding a vehicle in a target traveling direction to a braking/driving controller. The signal regarding the target braking/driving force is acquired based on information regarding a running route of the vehicle and a physical amount regarding a motion state of the vehicle. The vehicle control apparatus outputs a signal regarding a steering correction torque for correcting a steering torque according to a behavior of the vehicle to a steering force controller. The signal regarding the steering correction torque is acquired based on a vehicle-body slip angle of the vehicle and the target braking/driving force.

Methods and systems for operating axles of a vehicle are provided. In one example, a propulsion source of a first axle is operated in a torque control mode at a first torque and a propulsion source of a second axle is operated in a torque control mode at a second torque. Torque of the propulsion sources may be adjusted as a function of steering angle.

A system includes an acquisition unit that acquires an operation amount or a duration count, and a switching unit that switches a driving state. The switching unit switches the driving state to the cooperative driving state when the operation amount is equal to or greater than an intervention threshold and less than a start threshold or the duration count is equal to or greater than a first threshold and less than a second threshold during the autonomous driving state, switches the driving state to the autonomous driving state when the operation amount is less than the intervention threshold or the duration count is less than the first threshold during the cooperative driving state, and switches the driving state to the manual driving state when the operation amount is equal to or greater than the start threshold or the duration count is equal to or greater than the second threshold.

Aspects of the disclosure relate to a control system and a method for controlling generation of a steering wheel overlay signal to control positioning of a host vehicle. The control system comprises one or more controllers. The control system is configured to generate a steering wheel overlay signal for steering the host vehicle toward a target lane position; receive a driver intervention signal indicative of a driver intervention torque applied to a steering wheel of the host vehicle; and determine a driver intervention torque threshold based at least in part on an elapsed time since the generation of the steering wheel overlay signal. The control system is configured to mitigate the steering wheel overlay signal based at least in part on the driver intervention torque exceeding the driver intervention torque threshold.

A vehicle control ECU determines a road surface μ state of a forward road of a vehicle based on a front image. The vehicle control ECU changes, in accordance with a determined result, a split determination threshold value which is used to determine whether to perform a vehicle behavior stabilization control for stabilizing a behavior of the vehicle.

The present disclosure relates to a parking assistance system for searching for a parking space and parking a vehicle in the parking space, which includes: a determinator configured to determine whether or not the vehicle is in a stopped state based on movement information of the vehicle; a calculator configured to calculate inclination information, which is an inclination of the vehicle or road surface on which the vehicle is located, using an inclination sensor included in the vehicle; a memory configured to store traveling information including first inclination information when the first inclination information calculated by the calculator is less than predetermined threshold inclination information in a parking space searching step, and configured to maintain the first inclination information or update the traveling information by changing the first inclination information into second inclination information based on at least one of a stopped time during which the vehicle remains stopped and the second inclination information measured during the stopped time in a parking step in which parking is processed; and a controller configured to control the vehicle to move toward the parking space based on the traveling information stored in the memory.