An integrated control apparatus for an autonomous driving vehicle is provided. The integrated control apparatus includes a one-hand operation device that a user holds and operates with one hand a two-hand operation device that a user holds and operates with both hand. In the one-hand operation device, a deadman switch is disposed on the front of a grip of the housing under an acceleration trigger switch. In the two-hand operation device, a deadman switch is disposed on the bottom portion of the housing under an acceleration button switch and a brake button switch.

A vehicle display control device that is configured to: change, in accordance with a type of shift range that has been selected, display proportions of a first display region for displaying a shift range of a vehicle and a second display region for displaying a vehicle speed of the vehicle; and display the first display region and the second display region on a display.

A cleaning device for a surface, such as a windshield of a vehicle, has a housing that holds a spray bar, rotatable brush and a wiper blade. An engagement mechanism moves spray bar, the brush, and the wiper blade out from a disengaged position within the housing to an engaged position outside the housing so that they can be used to clean, brush, and dry the surface. After the spray bar, brush, and wiper blade are used to, respectively, clean, brush, and dry the surface, the engagement mechanism then moves the spray bar, the brush, and the wiper blade to a disengaged position within the housing.

Methods and systems for adapting an advanced driver assistance driving system of a vehicle. One system includes an electronic processor of an advanced driver assistance driving system. The electronic processor is configured to control the vehicle using a control parameter of the advanced driver assistance driving system. The electronic processor is also configured to activate a learning mode for the advanced driver assistance driving system and receive feedback associated with the control of the vehicle. The electronic processor is also configured to adjust the control parameter of the advanced driver assistance driving system based on the feedback and control the vehicle using the adjusted control parameter.

A method for outputting recommendations for energy efficient operation of a vehicle having at least two modes of operation, from which an operating mode is respectively selected by a drive controller, depending on the occurrence of specified triggers, for operating the vehicle. A change of operating mode caused by the trigger is determined. A frequency of the change of operating mode is incremented at every determination of the change of operating mode caused by the trigger. The frequency is analyzed by comparing the frequency of the change of operating mode a predetermined value. A message is generated on a case-by-case basis. The message is output via at least one output comprised by the vehicle.

A battery operation mode display device includes the mode display unit that displays a plurality of battery operation modes for controlling discharging and charging. The mode display unit sequentially displays a first mode indicator corresponding to a first battery operation mode identified in a first engine drive permission range, a second mode indicator corresponding to a second battery operation mode identified in a second engine drive permission range wider than the first engine drive permission range, and a third mode indicator corresponding to a third battery operation mode identified in a third engine drive permission range wider than the second engine drive permission range, among a plurality of battery operation modes identified for each drive permission range of the engine, in accordance with the drive permission range of the engine.

A cleaning device for a surface, such as a windshield of a vehicle, includes an active positioning system and a cleaning head. The active positioning system is configured to deploy from a storage position hidden from view within a covered storage space and to position the cleaning head upon the windshield. The active positioning system includes a first extension member and a second extension member that move relative to one another to position the cleaning head, and also move the cleaning head across the windshield along a path. The cleaning head can have a brush portion configured to agitate debris from the window, and a drying portion configured to dry the window after cleaning. The cleaning device can be controlled via a touch-screen display in the vehicle, enabling a user to direct that specific portions of the windshield be cleaned as desired.

A vehicle, which is a fuel cell vehicle, has an EV mode and an FC mode. In the EV mode, power generation by the FC stack is stopped and an electric power is supplied from a battery to a motor generator. In the FC mode, an electric power supplied from the FC stack to the motor generator is greater than an electric power supplied from the battery to the motor generator. In the EV mode, ECU controls an MID so that the MID displays the instantaneous electric power efficiency of the vehicle and does not display the instantaneous fuel efficiency of the vehicle. In the FC mode, ECU controls MID so that the MID displays the instantaneous fuel efficiency of the vehicle and does not display the instantaneous electric power efficiency of the vehicle.

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.

A display method for a hybrid vehicle includes displaying an engine icon representing the engine, a battery icon representing the battery, and a flow icon representing an energy flow between the engine icon and the battery icon on a display unit in accordance with a driving state of the hybrid vehicle. The display method includes displaying the flow icon in a display mode indicating that there is the energy flow between the engine and the battery when the battery is charged. The display method includes displaying the engine icon in a first display mode when the engine is stopped, displaying the engine icon in a second display mode when the engine is operated at engine rotation speed equal to or lower than reference rotation speed, and displaying the engine icon in a third display mode when the engine rotation speed is higher than the reference rotation speed.