A vehicle control system includes: a recognizer configured to recognize a surrounding environment of a vehicle; a driving controller configured to perform at least one of speed control and steering control of the vehicle according to a recognition result of the recognizer; and a receiver configured to receive a trigger transmitted from a vehicle exterior device in response to occurrence of a predetermined event to a user who is outside of the vehicle. The driving controller is configured to cause the vehicle to automatically travel to a boarding position of the user in response to the reception of the trigger by the receiver.

Systems and methods for using image analysis techniques to assess unsafe driving conditions by a vehicle operator are discloses. According to aspects, a computing device may access and analyze image data depicting the vehicle operator. In analyzing the image, the computing device may measure certain visible metrics as depicted in the image data and compare the metrics to corresponding threshold values, and may accordingly determine whether the vehicle operator is exhibiting an unsafe driving condition. The computing device may generate and present alerts that indicate any determined unsafe driving condition.

A method for performing driver performance comparisons is enabled, e.g., via in-vehicle capture of performance data from multiple vehicles or drivers. The performance comparisons are enabled via a geohash-based path analysis.

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.

Techniques are described that facilitate remotely interfacing with a vehicle touchscreen. According to an embodiment, a method is provided comprising determining touch controls included in a GUI configured for displaying on a touchscreen of the vehicle, wherein the touch controls provide for controlling functions of the vehicle based on first interaction with the touch controls as displayed on the touchscreen. The method further comprises generating a representation of the GUI for display via an auxiliary display of the auxiliary device, the representation comprising one or more graphical controls corresponding to one or more touch controls of the touch controls, and enabling remote control of one or more functions of the functions of the vehicle by the auxiliary device based on second interaction with the one or more graphical controls as displayed via the auxiliary display.

Techniques are described for remotely controlling functions of a vehicle without an integrated touchscreen. According to an embodiment, an auxiliary device is provided comprising a display and a processor that executes computer executable components stored in at least one memory. The computer executable component can comprise a feature acquisition component that determines electronic features of the vehicle that are respectively controlled by electromechanical controls of the vehicle, and a display component that displays a graphical user interface via the display wherein the graphical user interface comprises one or more graphical controls for controlling one or more features of the electronic features of the vehicle. The computer executable components further comprising a remote-control component that remotely controls the one or more features via interaction with the one or more graphical controls as rendered via the display.

Techniques are described that facilitate remotely interfacing with a vehicle touchscreen. According to an embodiment, a method is provided comprising determining touch controls included in a GUI configured for displaying on a touchscreen of the vehicle, wherein the touch controls provide for controlling functions of the vehicle based on first interaction with the touch controls as displayed on the touchscreen. The method further comprises generating a representation of the GUI for display via an auxiliary display of the auxiliary device, the representation comprising one or more graphical controls corresponding to one or more touch controls of the touch controls, and enabling remote control of one or more functions of the functions of the vehicle by the auxiliary device based on second interaction with the one or more graphical controls as displayed via the auxiliary display.

Systems and methods for avoiding illegal stopping zones are provided. In example embodiments, a networked system identifies a destination of a driver providing a transportation service to a user. The networked system monitors a user device of the driver, and infers, based on the monitoring, that the driver is planning to stop in an illegal stopping zone located a predetermined distance to the destination. The inference is based on device data such as accelerometer data or location data that is triangulated with known or derived illegal stopping zones. In response, the networked system causes presentation of a notification on a user interface of the device of the driver. The notification provides an indication of the illegal stopping zone. In some embodiments, the notification also provides an alternative stopping location determined by the networked system.

According to one embodiment, a user interface of a device comprising a display configured to output information related to a user interface of the multimedia system, wherein the user interface includes one or more icons indicative of an application of the multimedia system, and a processor in communication with the display and programmed to in response to a first input from a user, allow an arrangement of the one or more icons on the user interface and adjust an original size of the icons to a smaller size, set the arrangement of the one or more icons and adjust the smaller size icons to the original size icons, and output the original size icons on the display with the arrangement.

The disclosure relates generally to an in-vehicle feedback system, and more particularly, to an in-vehicle device with a display or graphical interface that collects driving data and provides feedback based on the driving data. The system may comprise an in-vehicle device that includes a graphical user interface and a processor and a data collection device wirelessly connected to the in-vehicle device. The in-vehicle device may be configured to receive vehicle telematics data from the data collection device and the processor may process the telematics data in real time and cause the telematics data to be displayed on the graphical user interface. The graphical user interface may include a speed display and an acceleration display.