A remote vehicle control device includes: a display unit; an operation unit configured for controlling a vehicle; a signal generating unit configured to generate control signals for the vehicle, based on operations on the operation unit; a communication unit configured to perform communication with the vehicle and another remote vehicle control device; and an authority managing unit that manages a control authority for the vehicle. Synthetic images showing a surrounding area of the vehicle as seen from a virtual viewpoint each are generated on the basis of plural images acquired by plural on-board cameras mounted on the vehicle, respectively, and the display unit displays the synthetic images. The communication unit transmits the control signals to the vehicle. The authority managing unit performs transfer of the control authority for the vehicle in cooperation with the another remote vehicle control device via the communication unit.

Cost of a precision farming guidance system is driven in part by the number of discrete system elements installed in a tractor including the steering actuator, guidance computer, user terminals, and the associated cable harnesses. An integrated guidance system arranges and integrates these separate elements into a base chassis and removable computer module to reduce cost and complexity while retaining flexibility to adapt to different vehicle configurations and to incorporate improved guidance computer technology into a common design platform.

A vehicle hitch assistance system includes a controller acquiring data from an external portable electronic device including position and orientation data of a trailer, including a coupler thereof, and deriving a vehicle path to align a hitch ball of the vehicle with the coupler using the position and orientation data of at least one of the trailer and the coupler.

When having determined that an own-vehicle has become unable to proceed in a traveling direction corresponding to a travel path of the own-vehicle and has stopped halfway through a travel path, a parking support device transmits information to an operation terminal, the information indicating a travel path and a place at which the vehicle has stopped on the travel path. When having received, from the operation terminal, specification information specifying a place to which the own-vehicle is to be moved, the parking support device sets, as a travel path of the own-vehicle, a path through which the own-vehicle is to be moved to the specified place, and outputs, to a vehicle control unit, control information for causing the own-vehicle to move to the specified place.

The disclosure is generally directed to systems and methods for executing an automated vehicle maneuvering operation. In one exemplary scenario, a driver stands on a curb and uses an application in a handheld device to execute a remote parking assist operation of his/her vehicle. The application may use a camera of the handheld device to provide to the driver, an image of a group of vehicles that includes his/her vehicle. The driver identifies his/her vehicle by dragging and dropping an icon upon the vehicle. The application then pairs the handheld device to the vehicle by instructing the vehicle to provide an audible and/or visual signal (beeps, flashing lights, etc.) to confirm the pairing. Upon pairing, a visual lock that is established by the application between the handheld device and the vehicle is used by the driver to automatically track and monitor the automated parking operation carried out by the vehicle.

A method includes detecting a continuous rotary input on a touchscreen of a portable device in communication with a vehicle, determining a steering angle and a steering direction based on a radius and a rotational direction of the continuous rotary input, and actuating a steering component of the vehicle based on the steering angle and the steering direction.

Embodiments are directed to a trailer maneuvering assistant system onboard a vehicle to communicate with and receive control instructions from a mobile device app. In one example embodiment, the app interface presents the user with an engagement input area and a curvature command area. The user must provide two types of touch inputs to the user interface portions: a first touch input that includes a complex gesture input in the engagement interface portion. In one example embodiment the complex gesture may be user input of a closed geometric shape such as a circle, oval, rectangle, or some other shape. The input may be complex in that it matches a canonical model for the respective shape. Matching may include an input that is coterminous with the canonical model within a threshold amount of error, and/or meets another guideline or threshold such as being a closed shape, or some other predetermined requirement(s).

The present disclosure is generally directed to a system and method of compensating for any forces induced by components of a robotic driving system, the robotic driving system including a turntable defining a steering axis and mounted to a steering wheel of a vehicle including an automated steering system, a robot frame mounted to the vehicle and including a support member, a transmission device coupled to the support member and operatively coupled to the turntable, a steering motor in driving engagement with the transmission device, a load sensor mounted between the support member and the transmission device at a known distance from the steering axis, and a controller in communication with the steering motor and the load sensor, the controller configured to adjust a steering torque generated by the steering motor to compensate for any forces induced by said robotic driving system to prevent overriding the automated steering system.

A vehicle control system includes: a terminal configured to be carried by a user; and a control device configured to execute a remote autonomous moving process to move a vehicle from an initial position to a prescribed stop position based on an input from the terminal and to stop the vehicle at the stop position. The remote autonomous moving process proceeds on condition of continuation of a reciprocating operation on the terminal by the user, and has a plurality of modes in which a vehicle speed to move the vehicle is set to values different from each other. The control device or the terminal is configured to select one of the plurality of modes based on a speed of the reciprocating operation.

A device for moving trailers (the device) enables anyone to easily maneuver and guide and park precisely in a specific location a trailer such as camper, utility, boat, horse or any other type of a tow behind a vehicle trailer without being attached to a vehicle. The device allows anyone to drive a parked trailer from its parked location to the towing vehicle with precise alignment to the ball hitch of the towing vehicle. The device is self-powered for the purpose of lifting and or lowering the trailer hitch on or off the hitch ball of the towing vehicle and a hydraulic pump and reservoir and a pair hydraulic motors for the forward and reverse movement and the left and right steering. The device is controlled with a wireless hand held remote through a Bluetooth operation system and or a phone application, which can be downloaded onto your smart phone.