A method of controlling vehicle stopping is provided. The method includes dividing an open space from a closed space, in which a gate is connected to the ground, to apply an open space stop control mode to the open space and to apply a closed space stop control mode to the closed space. Additionally, spatial division stop control is performed in which a control condition for each of an engine power, a vehicle interior temperature, and a battery state of charge (SOC) is varied between the open space stop control mode and the closed space stop control mode when a vehicle enters the closed space.

An arrangement for controlling a park area access system comprises a button (34) and a first control circuit (30) connected to the button (34) and suited to trigger the operation of the park area access system upon actuation of the button (34). The arrangement also comprises a receiver circuit (46); a controllable switch (44) connected in parallel to the button (34); and a second control circuit (42) suited to toggle the controllable switch (44) when the receiver circuit (46) receives a wireless instruction. A process for controlling a park area access system using such an arrangement is also described.

An approach is provided for visualizing future events to a passenger of a vehicle. The approach involves collecting sensor data, contextual data, or a combination thereof during an operation of a vehicle. The approach also involves processing the sensor data, the contextual data, or a combination thereof to predict a future event that is expected to occur proximate to the vehicle. The approach further involves generating a simulation of the future event. The approach further involves presenting the simulation in a user interface.

A driving assist ECU calculates a speed deviation V which is a magnitude of a deviation between a target speed Vset and a speed limit Vlim in a situation in which the target speed Vset and the speed limit Vlim are different from each other. When the speed deviation V is equal to or smaller than a threshold A, the driving assist ECU sets an accept prohibition flag to 1. When the speed deviation V is higher than the threshold A, the driving assist ECU sets the accept prohibition flag to 0. When the accept prohibition flag is 1, the driving assist ECU regards/treats a long-push operation of an operating unit not as an accept operation, but as an acceleration operation or a coast operation.

A drive assist apparatus, for vehicle, includes a position detector, a storage, a display, an operation unit, and a controller. The position detector acquires own vehicle position information on the basis of a position signal received from positioning satellites. The storage stores road map information. The display displays a symbol representing the own vehicle at a position indicated by the own vehicle position information acquired by the position detector, and displays the road map information around the own vehicle information acquired by the position detector. The operation unit receives a relative moving operation. The relative moving operation allows the symbol representing the own vehicle and the road map information both displayed on the display to move relative to each other in a vehicle width direction. The controller corrects the own vehicle position information in accordance with the relative moving operation received by the operation unit.

An approach is provided for visualizing future events to a passenger of a vehicle. The approach involves collecting sensor data, contextual data, or a combination thereof during an operation of a vehicle. The approach also involves processing the sensor data, the contextual data, or a combination thereof to predict a future event that is expected to occur proximate to the vehicle. The approach further involves generating a simulation of the future event. The approach further involves presenting the simulation in a user interface

A method is disclosed for operating a motor vehicle having a plurality of driver assistance systems, wherein the method includes setting, via an operator interface of the motor vehicle, an assistance degree parameter, which indicates the extent to which support for a driver by the driver assistance systems is desired. The method also includes setting, via the operator interface of the motor vehicle, at least one additional parameter, which is related to the driving operation of the motor vehicle. The method additionally includes specifying, by a processing device of the motor vehicle, at least one operating parameter for each driver assistance system, in accordance with which operating parameter the driver assistance system is operated, as a function of the assistance degree parameter and the additional parameter(s). A motor vehicle is also disclosed that performs the method.

Method for controlling a car, in particular a sports car, provided with a relative power train, relative braking devices and relative steering means, the method being based on a joystick comprising a lever, arranged in the car to identify a forward tilt and a backward tilt parallel to a longitudinal development of the car for interacting with said power train and with said braking devices, and two side tilts to the left and to the right for interacting with said steering means so as to determine a trajectory of the car, wherein the method, according to a first operating condition, comprises a first step of respectively associating said forward tilt and said backward tilt with a proportional forward and backward acceleration of the car.

An apparatus for lane change control for a vehicle may include: a determination device to determine lane change conditions for a first vehicle and a second vehicle, which are each travelling in a target lane to which a host vehicle performs a lance change; and a controller to perform the lane change control for the host vehicle when both the lane change conditions for the first and second vehicles are met. In particular, the first vehicle is located behind the host vehicle, and the second vehicle is located in front of the host vehicle.

A computing system for a vehicle includes one or more processors for controlling operation of the computing system, and a memory for storing data and program instructions usable by the one or more processors. The one or more processors are configured to execute instructions stored in the memory to determine when the vehicle is currently in a user-selected predefined driving situation and, responsive to the determination, control operation of the vehicle to implement a vehicle response mode associated with the user-selected predefined driving situation. The vehicle response mode may include an initial control mode specifying one or more initial indicators of the vehicle response mode, and a conditional secondary control mode specifying one or more secondary indicators of the vehicle response mode. The one or more initial indicators and the one or more secondary indicators are configured to be perceivable by a person exterior of the vehicle.