[Object] To provide more appropriate input by using an input section installed on a controller, which is operated by a user.

[Solution] Provided is a control device including: an input detection section configured to detect input provided by a user to an input section installed on a controller that is operated by the user; and an erroneous input determination section configured to determine whether or not the input is erroneous input, on the basis of the input.

A vehicle display control device includes: a driving mode acquisition section that acquires information on which of a manual driving mode or an autonomous driving mode is a driving mode; an operation intervention detection section that, in a case in which the driving mode acquired by the driving mode acquisition section is the autonomous driving mode, detects a driving operation intervention by the vehicle occupant; and a display control section that displays vicinity information of the vehicle at a display unit provided at a vehicle cabin at least in a case in which the driving mode acquired by the driving mode acquisition section is the autonomous driving mode, wherein, in a case in which a driving operation intervention is detected by the operation intervention detection section, the display control section changes background information of the vicinity information and displays the background information at the display unit.

In various examples, systems and methods are disclosed herein for a vehicle command operation system that may use technology across multiple modalities to cause vehicular operations to be performed in response to determining a focal point based on a gaze of an occupant. The system may utilize sensors to receive first data indicative of an eye gaze of an occupant of the vehicle. The system may utilize sensors to receive second data indicative of other data from the occupant. The system may then calculate a gaze vector based on the data indicative of the eye gaze of the occupant. The system may determine a focal point based on the gaze vector. In response to determining the focal point, the system causes an operation to be performed in the vehicle based on the second data.

An operating device includes a lock mechanism unit that regulates relative movement of an operating unit with respect to a supporting member, and a controller that releases locking of the lock mechanism unit when input of an operator is detected by an operation detector. When contact of a finger with a surface panel is detected by a first detection member, locking of the operating unit by the lock mechanism unit is released. In addition, when a pressing operation to the operating unit is detected by a second detection member, control is performed so that a response force providing mechanism operates.

A display control device includes a processor. The processor being configured to: receive proposal information relating to a proposal that requests an instruction from a vehicle occupant of a vehicle; receive an operation signal that is outputted in accordance with an operation of the vehicle occupant; and in a case of receiving the proposal information, change display of a display device provided within the vehicle from a usual image to an image that includes a proposal image relating to the proposal, and, during a predetermined time period from start of display of the proposal image, prohibit reflection of the operation signal in the instruction.

A driving assist system includes a steering wheel contact position detector, a steering torque detector, and a driving mode setting calculator. The steering wheel contact position detector includes a plurality of contact sensors disposed in a segmented state on a circumference of a holding part provided on a steering wheel, and is configured to detect a position on the steering wheel at which a driver makes a contact with the steering wheel. The driving mode setting calculator is configured to set a driving mode on the basis of a driving condition. The driving mode setting calculator is configured to determine whether a steering torque detected by the steering torque detector is a steering override intended by the driver or is a false detection, on the basis of the steering torque detected by the steering torque detector and a position at which the contact is detected by the contact sensors.

A control system for a dump truck or trailer having a telescoping hoist is disclosed. The control system includes an integrated electronic control unit which receives sensor information regarding at least a hydraulic pump, a power take-off, a first inclinometer and a second inclinometer and uses this information to send warning to a user display and to sends control information to at least a hydraulic fluid control valve and optionally other devices on the truck or trailer as well.

A device and to a method for controlling a highly automated vehicle, as well as a portable unit for remotely controlling the highly automated vehicle, the highly automated vehicle being able to independently carry out driving maneuvers without the intervention of the driver or a vehicle occupant. The device for controlling is connected to the portable unit. The device for controlling receives a signal from the portable unit that the portable unit has detected a dropping by the vehicle driver or a vehicle occupant. Upon detection of a free fall, the presently independently carried out driving maneuver is automatically aborted or terminated.

The invention relates to a sensor device for a vehicle for capacitively detecting input means in the region of a detection area, having a first sensor electrode and a second sensor electrode and an evaluation unit which is electrically connected to a respective first connection of the first sensor electrode and of the second sensor electrode via connection lines. The object of the invention is to provide a particularly accurate and reliable sensor device for a vehicle for capacitively detecting input means. The object according to the invention is achieved by using respective second connections on the first sensor electrode and on the second sensor electrode and by means of corresponding methods for detecting the presence of input means and for detecting faults.

Systems and methods are provided herein for adaptive user input boundary support for remote vehicle motion commands. The systems and methods described herein may be used to allow more flexibility in continuous inputs provided to trigger commands to a vehicle to perform an autonomous function, such as Remote Park Assist (RePA). The systems and methods may allow RePA to continue even if the continuous input is not provided in the form of a perfect circle or if the continuous input drifts gradually over time.