A control system and method for controlling a vehicle's functions using an in-vehicle gesture input, and more particularly, a system for receiving an occupant's gesture and controlling the execution of vehicle functions. The control system using an in-vehicle gesture input includes an input unit configured to receive a user's gesture, a memory configured to store a control program using an in-vehicle gesture input therein, and a processor configured to execute the control program. The processor transmits a command for executing a function corresponding to a gesture according to a usage pattern.

A display control system includes an input unit to receive position information of a knob, a memory to store a display control program in relation to a position of the knob, and a processor to execute the display control program to change a display of content in a display in consideration of the position information of the knob in relation to movement of the knob.

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.

An electric vehicle charging management system has a dashboard apparatus, a vehicle controller, and a power battery apparatus. The dashboard apparatus stores multiple charging parameters that are adjustable. The multiple charging parameters include a charging power, a charging capacity, and a charging time frame. The vehicle controller is connected to the dashboard apparatus. The vehicle controller enters a charging operation mode when receiving a wake-up signal to read the multiple charging parameters from the dashboard apparatus and output the multiple charging parameters. The power battery apparatus receives a charging power source. The power battery apparatus has a control unit and an energy storage unit. The control unit is connected to the vehicle controller. When the control unit receives the multiple charging parameters from the vehicle controller, the control unit controls the charging power source to charge the energy storage unit according to the multiple charging parameters.

The present application discloses systems and methods to present information to recreational vehicle riders and to provide customizable visual information to recreational vehicle riders. The present application further discloses systems and methods to connect and transmit audio information between a driver portable communication device and a driver audio interface device through the recreational vehicle and audio information between a passenger portable communication device and a passenger audio interface device.

The present invention relates to a vehicle user interface device including a display configured to display a first Augmented Reality (AR) graphic object at a point in a display area corresponding to a first point, and at least one processor configured to obtain distance data between a vehicle and the first point and change the first AR graphic object based on the distance data.

A vehicle display device according to an embodiment of the disclosure includes a display that displays, as an image, functions for various pieces of vehicle operation information, a knob that is electrically interlocked with the display and selectively operates a corresponding function of the display according to left-right movement thereof, a guide rail that provides a movement path of the knob and divides a plurality of functional areas interlocked with the functions displayed on the display, and a guide part in which magnets having different polarities are alternately arranged in a lengthwise direction of the guide rail to automatically guide a location of the knob.

Techniques are disclosed for creating and presenting a graphical user interface for display of autonomous vehicle behaviors. The techniques include determining a trajectory of a vehicle operating in a real-world environment. Sensors of the vehicle obtain sensor data representing an object in the real-world environment. A maneuver of the vehicle to avoid a collision with the object is predicted based on the sensor data and the trajectory of the vehicle. It is determined that a passenger comfort level of a passenger riding in the vehicle will decrease based on the maneuver of the vehicle. The passenger comfort level is measured by passenger sensors of the vehicle. A graphical user interface is generated including representations of the vehicle, the object, and a graphic, text, or a symbol alerting the passenger of the predicted maneuver. The graphical user interface is transmitted to a display device of the vehicle.

A display system of a vehicle, and a control method thereof includes: a user input device; a head-up display configured to project a virtual image including augmented reality contents and to adjust a projection position of the augmented reality contents according to predetermined driver viewpoint information and left and right direction offset; and a controller configured to correct the driver viewpoint information or the left and right direction offset according to a control input received through the user input device, wherein the left and right direction offset indicates a degree to which the augmented reality contents are shifted left or right.

A method includes receiving sensed signal data from at least one circuit based on a user in proximity to at least one electrode corresponding to the at least one circuit. Hover detection data indicating a detected hover in proximity to an interactable element of a vehicle is generated. Button feedback display data indicating the interactable element is generated based on the hover detection data. Display of the button feedback display data via a display device is facilitated.