A vehicle control system includes a target drive force calculation unit, an arithmetic unit, a stop holding unit, a power-running-generative drive force calculation unit, and a traveling mode selection unit. The arithmetic unit calculates required drive force and required brake force based on target drive force calculated by the target drive force calculation unit. The arithmetic unit calculates the required drive force by setting the required brake force to stop hold brake force or greater if an engine traveling mode is selected at an immediately preceding timing by the traveling mode selection unit. The arithmetic unit calculates the required brake force by setting the required drive force to less than or equal to power-running-generative drive force calculated by the power-running-generative drive force calculation unit if an electric vehicle traveling mode is selected at the immediately preceding timing by the traveling mode selection unit.

A vehicle control device has a processor configured to determine whether or not a problem exists with the level of active operation by the driver and when there is a problem with the driver, to set a stopping location for the vehicle on a traveling lane and to determine whether or not another traffic lane is adjacent on the side of the stopping location opposite from a passing lane and, when another traffic lane is adjacent, to determine whether or not the stopping location is within a stop avoidance area set in the traveling lane, based on an adjacent start location or an adjacent end location and, when the stopping location is within the stop avoidance area, to generate a stopping plan for stopping of the vehicle at a location between the adjacent start location and the adjacent end location other than in the stop avoidance area.

A stop assist system for moving a moving body to a stop position and making the moving body stop at the stop position includes: an external environment recognizing unit that recognizes an external environment of the moving body; and a moving body control unit that executes a driving process to make the moving body travel to the stop position based on a recognition result of the external environment recognizing unit. The moving body control unit suspends the driving process when, while the moving body is traveling to the stop position, the moving body control unit determines, based on the recognition result, that there is an object within a range of a prescribed lateral threshold value on a lateral outside of the moving body and the object extends over a prescribed longitudinal threshold value or more along a travel direction within the range.

A system and a method automatically longitudinally guide a motor vehicle. The system is used to automatically brake the motor vehicle to a standstill on the basis of a detected infrastructure component which requires a braking of the motor vehicle to a standstill. The system includes a sensor unit which is designed to detect an infrastructure component that requires a braking of the motor vehicle to a standstill, a first determining unit which is designed to determine a standstill position on the basis of currently provided information of the sensor unit upon detecting the infrastructure component, a second determining unit which is designed to determine an adapted standstill position upon no longer detecting the infrastructure component on the basis of the determined standstill position when the infrastructure component was still detected, and a control unit which is designed to automatically initiate a braking to the standstill into the determined standstill position or the determined adapted standstill position.

A vehicle control apparatus is mounted on a vehicle including an emergency stop function to detect an abnormal state of a driver and automatically stop the vehicle. The vehicle control apparatus provides control at a time of stopping the vehicle and includes process execution sections and a process stop section. The process execution sections perform predetermined emergency processes in response to the emergency stop function stopping the vehicle; the emergency processes control instruments mounted on the vehicle and use a battery of the vehicle as a driving power source. The process stop section stepwise stops at least part of the emergency processes performed by the process execution sections based on a predetermined stop sequence.

A technique for simplifying the structure of an idling stop device. The idling stop device 100 includes a deceleration detector 200 which detects decelerations of a vehicle. The idling stop device 100 also includes an estimation part 350 which acquires, based on the deceleration detected by the deceleration detector 200, first deceleration when a vehicle is decelerated to a preset speed of less. Based on the acquired first deceleration, the estimation part 350 estimates a first brake pressure applied to the vehicle when the vehicle is decelerated to the preset speed or less.

In a vehicle control system (1, 101, 201) configured for autonomous driving, a control unit executes a stop process by which the vehicle is parked in a prescribed stop area when it is detected that the control unit or a driver has become incapable of properly maintaining a traveling state of the vehicle, and a stop maintaining process for keeping the vehicle parked following the vehicle coming to a stop in the stop process. The control unit keeps the brake lamp turned on while the stop maintaining process is being executed.

A vehicle control device executes a warning control for a driver when the driver is in an abnormal state, and executes a stop control for stopping an own vehicle when the abnormal state is continued for a predetermined time threshold or more from a time point at which the warning control is started. In a first period from a time point at which the warning control is started to a time point at which the stop control is started, the vehicle control device determines whether there is another vehicle behind the own vehicle, and when the control device determines that there is no other vehicle behind the own vehicle, a specific deceleration control that temporarily decelerates the own vehicle is executed.

An apparatus includes a torque circuit and a clutch circuit. The torque circuit is structured to monitor a torque demand level of an engine. The clutch circuit is structured to (i) disengage an engine clutch of a transmission to decouple the engine from the transmission in response to the torque demand level of the engine falling below a threshold torque level and (ii) disengage a motor-generator clutch of the transmission to decouple a motor-generator from the engine in response to the torque demand level of the engine falling below the threshold torque level. The motor-generator is directly coupled to the transmission.

The disclosure relates to a method for controlling an internal combustion engine. The internal combustion engine includes a cylinder and a piston, which runs in the cylinder, together delimiting a working chamber. The working chamber is supplied with fresh air from an intake section via an inlet valve and is connected to an exhaust manifold via exhaust valves. The internal combustion engine includes a variable valve actuation system for the actuation of the inlet valves, controlling the opening time and/or the closing time and/or the lift. A strategy for shutting down the internal combustion engine includes controlling the inlet valves of individual or all working chambers in such a way that the transfer of fresh air from the intake section to the exhaust manifold is reduced or avoided and that the drag torque of the intake combustion engine is reduced.