Upper and lower limits of one or more parameters are established for each of a plurality of states of operation of a vehicle. One of the plurality of states for operating the vehicle is identified based at least in part on the parameters, data describing a human operator, and data describing an environment around the vehicle. A vehicle subsystem is actuated according to an operation mode corresponding to the current operating state.

An information presenting apparatus is used in an autonomous vehicle capable of switching between autonomous driving control and manual driving control. The information presenting apparatus determines a response action for checking that the driver is ready to take over when the autonomous driving control is switched to the manual driving control, performs control for requesting the driver to perform the response action determined, and detects the response action performed by the driver.

A driving information generating section 20 successively generates as driving information diverse types of information indicative of a driving state of a vehicle. A dangerous driving determining section 31 determines whether dangerous driving is underway on the basis of the driving information generated by the driving information generating section 20. A supplementary information acquiring section 32 acquires state supplementary information manually or automatically upon determination of dangerous driving by the dangerous driving determining section 31, and associates the acquired state supplementary information with the result of the determination of dangerous driving. An information communication section 34 transmits the result of the determination of dangerous driving and the state supplementary information to an information management apparatus 40. The information management apparatus 40 can recognize the state of the case in which dangerous driving is underway based on the state supplementary information, and correctly determine validity of the result of the determination of dangerous driving.

A driver monitoring system for a vehicle includes a vehicle data acquisition system operable to determine vehicle status information after a vehicle is involved in a collision including information pertaining to (i) the collision of the vehicle, (ii) an overturning of the vehicle, (iii) water intrusion into the vehicle and (iv) airbag deployment. A driver status information acquisition system is operable to determine health parameters of the driver of the vehicle. A communication system of the vehicle is operable to wirelessly communicate with a remote assistance system. Responsive to the vehicle status information determined by the vehicle data acquisition system and the driver health parameters determined by the driver information acquisition system, the communication system wirelessly communicates information to the remote assistance system and, responsive to the communication received by the remote assistance system, the remote assistance system determines an appropriate response to the vehicle collision.

A vehicle control system for a vehicle includes a plurality of sensors disposed at a vehicle and having respective fields of sensing exterior of the vehicle. A processor is operable to process data captured by the sensors, and a control, responsive to processing by the processor of data captured by the sensors, controls a plurality of vehicle systems and is capable of autonomous control of the vehicle to autonomously drive the vehicle along a road. The vehicle control system includes a user input that is selectively actuatable by an occupant of the vehicle so that the occupant can select one of at least (i) a non-autonomous mode where the occupant has driving control of the vehicle and non-autonomously drives the vehicle along the road, and (ii) an autonomous mode where said control autonomously drives the vehicle along the road.

A vehicle includes a detection system configured to acquire data regarding operation of the vehicle, and a robotic driving device configured to provide robotic control of the vehicle. The vehicle also includes a control system configured to determine whether the robotic driving device is activated, such that the vehicle is in robotic driving mode; receive a request by a prospective operator of the vehicle to deactivate the robotic driving device to initiate a manual driving mode; determine whether the prospective operator is impaired based on the data; and selectively grant or refuse the request based on the determination.

Methods and systems for monitoring use, determining risk, and pricing insurance policies for a vehicle having one or more autonomous or semi-autonomous operation features are provided. According to certain aspects, an identity of a vehicle operator may be determined and a vehicle operator profile and/or operating data regarding autonomous operation features of the vehicle may be received after the vehicle operator opts into a rewards program and agrees to share their data. Autonomous operation and vehicle operator risk levels associated with operation of the autonomous or semi-autonomous vehicle may be determined. Based upon the risk levels and/or comparison thereof, one or more autonomous operation features may be disengaged. A preparedness level of the vehicle operator to assume or reassume control of operating the vehicle is determined prior to disengagement. If satisfactory, an alert is presented to the vehicle operator prior to disengagement of the autonomous operation features.

A method and an apparatus for safely parking a vehicle, wherein after identifying an emergency situation of the motor vehicle, an emergency stopping position region is selected from a digital map, and the vehicle is parked within the emergency stopping position region by an automatic driving function. The method includes registering the surroundings, determining stationary objects and conditions in the vicinity of the vehicle within the selected emergency stopping position region, checking the conditions in the vicinity of the vehicle and the stationary objects within the emergency stopping position region regarding parking the vehicle in an optimized manner and determining an optimized emergency stopping position within the emergency stopping position region, and parking the vehicle at the optimized emergency stopping position within the emergency stopping position region using the automatic driving function.

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.

Interacting with the driver based on the driver's context can keep help keep the driver alert. The context can be determined determining driver characteristics including the interests and by monitoring the circumstances surrounding the driver, such as the state of the driver using sensors included in the vehicle, the state of the vehicle, and the information about the driver's current locale. The characteristics and the monitored circumstances define the context of driver. Information of interest to the driver is obtained and is used to generate actions that are recommendable to the driver based on the driver's context. The actions are used to keep the driver alert.