A steering determination device determines a steering state in which a driver of a vehicle is steering a steering wheel of the vehicle. The device includes a torque recognition unit configured to recognize a steering torque based on a measurement result of a torque sensor provided on a steering shaft, an acceleration recognition unit configured to recognize longitudinal acceleration or lateral acceleration, a threshold value setting unit configured to set a threshold value for the determination of the steering state, based on the longitudinal acceleration or the lateral acceleration, and a steering determination unit configured to determine that the driver is in the steering state if the steering torque is equal to or greater than the threshold value. The threshold value setting unit is configured to set the threshold value such that the threshold value decreases as an absolute value of the longitudinal acceleration or the lateral acceleration decreases.

A steering control device for a vehicle controls a steering device having a steering mechanism and a drive unit configured to provide the steering mechanism with steering force for the wheels. The steering control device includes a detection unit to detect the steering angle; and a control unit to calculate a target value of a current to be supplied to the drive unit as a current command value, and execute automatic steering control to automatically control steering of the vehicle by causing the drive unit to be supplied with the current of the current command value. When an absolute value of the steering angle comes to a predetermined first threshold or more during the automatic steering control, the control unit decreases an upper limit value of an absolute value of the current command value as the absolute value of the steering angle increases.

A vehicle system includes communication circuitry programmed to communicate with a controller that is removable from an autonomous vehicle. The system further includes a processor programmed to receive control signals, which are associated with manually controlling the autonomous vehicle in a non-autonomous mode, transmitted from the controller. The processor is further programmed to output commands to at least one vehicle subsystem in accordance with the control signals transmitted from the controller while the vehicle is operating in a non-autonomous mode.

An apparatus for controlling remote parking in a vehicle is provided. The apparatus includes an ultrasonic sensor that measures a distance from the vehicle to an obstruction and a receiver that receives a surround view monitoring (SVM) image. A controller executes remote parking of the vehicle by selectively using the distance from the obstruction, the distance being measured by the ultrasonic sensor, and the SVM image received by the receiver.

A control device for an unmanned vehicle includes a temperature data acquisition unit acquiring temperature data of hydraulic oil supplied to a first hydraulic actuator actuating a steering device of the unmanned vehicle, and a command output unit outputting a change command for changing a travel parameter of the unmanned vehicle based on the temperature data.

The invention relates to an electronic parking assistance device (1) for a motor vehicle (10), comprising: a housing (2) provided with an antenna (3), a camera (6) that is contained, at least in part, in the housing, and a control unit (7) that is contained in the housing and is connected to said antenna. According to the invention, the housing is provided with at least one other antenna (4) that is connected to the control unit, and this control unit is suitable for selecting each antenna and for sending and receiving signals exclusively via the selected antenna.

A steering-system for an automated vehicle is provided. The system includes an object-detector and a controller. The object-detector indicates a height and/or a width of an object approached by a host-vehicle. The controller is configured to steer the host-vehicle and is in communication with the object-detector. The controller steers the host-vehicle to straddle the object when the height of the object is less than a ground-clearance of the host-vehicle, and/or the width of the object is less than a track-width of the host-vehicle.

A steering-wheel assembly includes an actuator, an actuator controller, a steering wheel, an attachment, and a data connector (referred to hereinafter as a first data connector). The actuator controller includes a processor and a memory and is communicatively coupled to the actuator. The steering wheel is rotatably coupled to the actuator. The attachment is coupled to the actuator. The first data connector is mounted on the attachment and in communication with the actuator controller. The actuator controller is programmed to instruct the actuator to rotate the steering wheel based on steering-wheel control data provided via the first data connector.

A vehicle battery mounting structure has: a battery frame lower member that is made of resin, and that is disposed at vehicle transverse direction inner sides of energy absorbing members provided at a lower side of a floor panel, and that, together with a battery frame upper member, structures a battery frame that supports a battery; a lower ductile member having a lower main body portion that is joined to vehicle transverse direction outer side end portions of the battery frame lower member, and lower flange portions that are fixed to a bottom surface side of the floor panel; and inclined walls that are formed at vehicle transverse direction outer side end portions of the battery frame lower member, and that are inclined from vehicle transverse direction outer upper sides toward vehicle transverse direction inner lower sides.

A vehicle maneuvering apparatus includes an imaging device configured to capture image data and a controller in communication with a vehicle maneuvering system. The controller is configured to identify a coupler position of a trailer in the image data and compare a coupler height of the coupler position with a hitch height of a hitch ball. In response to the coupler height being insufficient to clear the hitch height, the controller is further configured to calculate a target position laterally offset from the coupler position and communicate the target position to the vehicle maneuvering system.