The present disclosure relates to a method for providing a retreat space for the periodic recuperation of a person. In this case, the interior of a vehicle serves as the retreat space. Said vehicle may be a person's own passenger vehicle or a rented vehicle. Since the retreat space is only used for brief recuperation, e.g., during a lunch break, the space is prepared such that it can fulfill the recuperation requirements from the very start. For this purpose, a request message is sent to the vehicle, by means of which request message the vehicle is prepared as a retreat space for the person. Said preparation consists in configuring the vehicle interior, at least in terms of lighting and/or climatic conditions and/or entertainment facilities, to serve as a retreat space for the recuperation of said person at the reserved time in accordance with the request message. The vehicle may also receive a reservation request message from a service provider who provides vehicles for rent.

A mobile device, vehicular electronic device, method and medium thereof are disclosed. The mobile device includes a communicator, display, memory/medium, and processor. The processor implements one method, including: receive context information and driving state information from the vehicular device, generate a control interface based on the received information, and output the control interface. The vehicular control device includes a communicator, memory/medium, and processor, which transmits the context information and drive state information to the mobile device, receives input information generated through the control interface as transmitted by the mobile device, and executes a corresponding control operation based on the input information.

The invention relates to systems and methods for executing functions on a mobile device based on gestures and commands of a user inside a vehicle. The system comprises a head-up display that reflects the screen of a mobile device and a motion-detection device connected to the mobile device. The motion-detection device is configured to gather information on the movement of the user's fingers regardless of whether or not the user's hands are on the steering wheel of the vehicle. The mobile device is configured to classify the movement of the user's fingers in a predetermined gesture associated with a predefined instruction, based on which a function is executed on the mobile device.

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 example system according to an example of the present disclosure includes a wireless headset having a speaker and a microphone. Control circuitry is disposed in a vehicle and is in communication with a plurality of vehicle systems. The control circuitry is configured to provide alerts through the speaker based on information from the plurality of vehicle systems indicating occurrence of trigger events, and to determine when to provide each alert based on a priority level of the alert within a multi-level hierarchy of priority levels.

A driving control system including a sensor unit, a data storage unit and a control unit. The sensor unit is arrangeable in the vehicle and configured to detect at least one driving parameter of the vehicle during travelling. The control unit is configured to generate at least one driving mode based on the at least one driving parameter. The data storage unit is configured to store the at least one driving mode. The control unit is configured to receive an input whether the vehicle continues traveling in a current driving mode or changes to one of the driving modes stored in the data storage unit. The control unit is further configured to simulate the driving mode based on the input, even though the vehicle stops travelling.

A driving control system including a sensor unit, a data storage unit, a user communication means and a control unit. The sensor unit is arrangeable in a first vehicle and configured to generate at least one user-specific driving parameter of at least one user travelling with the first vehicle. The at least one user-specific driving parameter is based on a driver's driving behavior of the first vehicle. The user communication means is configured to receive an input of the user to store the at least one user-specific driving parameter in the data storage unit and activate the stored at least one user-specific driving parameter in a second vehicle to be occupied by the user. The control unit is configured to transmit the at least one user-specific driving parameter of the user from the data storage unit to the second vehicle.

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 an intuitive user interface and control input mechanism for controlling the movement of the vehicle and trailer with one hand. In particular, the control input mechanism performs a method to determine an arrangement of controls for use with one hand.

A charging device for an electric vehicle includes a network connection unit, a display light-panel, and a processor. The network connection unit is coupled to a server through a network and receives an indication of an operation of a charging procedure performed by a user device corresponding to the electric vehicle via the network. The display light-panel has an optical light-guiding component and a backlight module, wherein the optical light-guiding component has a fixed pattern printed thereon and the backlight module includes light sources, and the optical light-guiding component and the light sources are respectively disposed to operate the display light-panel in at least one illumination mode. The processor respectively changes the illumination mode of the display light-panel in response to the received indication, such that the display light-panel changes the light sources to generate an interaction display effect corresponding to the operation of the charging procedure.

A controller in a vehicle includes an obtaining unit that obtains facility information on a charging facility that can charge a power storage mounted on the vehicle, the facility information including position information and utility information in association with each other, the position information indicating a position of the charging facility, the utility information indicating an electric utility that manages the charging facility. The controller further includes at least one of a first notification unit and a second notification unit. The first notification unit causes a notification apparatus to give first information that indicates an electric utility, by using the facility information obtained by the obtaining unit. The second notification unit causes the notification apparatus to give second information that indicates a position of a charging facility, by using the facility information obtained by the obtaining unit.