The systems and methods disclosed herein are configured to provide a mobile device for remotely controlling the movement of a vehicle and trailer. The mobile device provides a user engagement input for display and use of a control input. The control input may be used to generate a signal for controlling the movement of the vehicle and trailer.

A method for controlling an autonomous vehicle includes using one or more computing devices to transmit a request for a trip. The trip is from a pickup location to a destination location. The method also includes determining the autonomous vehicle for the trip is within a predetermined distance from the pickup location, providing a set of component controls to receive user input at a user interface after the determining. The set of component controls includes interactive controls for identifying or accessing the autonomous vehicle. A first user input is received at the user interface for one or more of the set of component controls, and control instructions for the autonomous vehicle based on the first user input are transmitted.

A controlling and warning system based on traffic conditions feedback and a method thereof are disclosed. In the controlling and warning system, a camera disposed on a rear of a vehicle body is configured to generate and transmit a rear video to a controlling host, and the controlling host identifies a vehicle object in the rear video and calculates a separation distance between the vehicle object and the vehicle body; the vehicle object is inputted into a large-sized vehicle recognition model which is built based on artificial intelligence neural network and trained completely, to recognize whether the vehicle object is a large-sized vehicle; when the vehicle object is recognized as the large-sized vehicle and the separation distance reaches to a safe distance, a warning signal is generated. Therefore, the technical effect of improving the warning immediacy of an approaching large vehicle can be achieved.

A vehicle control device is a vehicle control device mounted in a vehicle and includes an information provider configured to transmit information on a route from a parking position to a boarding position of the vehicle to a terminal device.

The present invention obtains an assistance system capable of assisting with function setting of a straddle-type vehicle by a rider, a portable wireless terminal used for such an assistance system, a control method for such an assistance system, a control method for such a portable wireless terminal, and a program run on such a portable wireless terminal.

In an assistance system (1), an acquisition section (51) of a portable wireless terminal (50) wirelessly acquires information on the function setting operated on an input device (11) of a straddle-type vehicle (10), and an input section (52) of the portable wireless terminal (50) provides a guidance corresponding to the information on the function setting operated on the input device (11) of the straddle-type vehicle (10) when accepting the operation of the function setting by the rider.

The technology relates to providing an enhanced user experience for riders in autonomous vehicles. Two or more displays may be arranged at different locations within a vehicle to provide notifications, alerts and control options. Information may be dynamically and automatically switched between these displays, as well as a rider's own personal communication device(s). What information to present on each screen can depend on factors including how many riders are in the vehicle, their seating within the vehicle, how their attention is focused and/or display location and size. Certain information may be mirrored or otherwise duplicated among multiple screens while other information can be presented asymmetrically on different screens. Presented information may include a “monologue” from the vehicle explaining why a driving action is taken or not taken, alerts about important conditions, buttons to control certain functionality of the vehicle, or other information that may be of interest to the rider.

A detector detects an overall fill level of a receiving vehicle. A mobile device on the receiving vehicle includes a mobile application that receives and displays the overall fill level of the receiving vehicle. The overall fill level can be overlaid on a geographic map that shows locations of multiple receiving vehicles, in which case an overall fill level indicator for each receiving vehicle is displayed on the geographic map as well.

Disclosed is an electronic device for a vehicle, including a processor acquiring image data acquired by a camera mounted in a vehicle, determining a riding intention of an outside person based on the location, posture, and gesture of the outside person detected from the image data, and generating a control signal to stop the vehicle based on the riding intention.

A system includes a processor configured to determine an applicable pre-defined vehicle system state set, defining preferred vehicle system states when a driver is away from a vehicle. The processor is also configured to determine a driver exit-event while a vehicle state in the state set varies from a preferred setting and notify a driver mobile device of the variance, responsive to the exit event.

A fill control system on a harvester detects that a receiving vehicle is to be repositioned relative to the harvester. The fill control system generates a signal indicative of how the receiving vehicle is to be repositioned relative to the harvester. The harvester sends the signal to a mobile device that is remote from the harvester. A mobile device receives an indication from a fill control system on a harvester that indicates how a receiving vehicle is to be repositioned relative to the harvester. The mobile device controls a user interface mechanism to generate an output indicating how the receiving vehicle is to be repositioned relative to the harvester.