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.

In a travel control apparatus for a vehicle, a travel environment information acquisition unit acquires travel environment information, and a travel information detector detects travel information relating to the vehicle. The apparatus executes automatic driving control based on such information pieces. A vehicle peripheral object detector detects an object around the vehicle, separately to the travel environment information acquisition unit. An environment information acquisition failure detector detects an acquisition failure in the travel environment information acquisition unit. Upon an acquisition failure of the travel environment information, an evacuation controller executes evacuation control by evacuating the vehicle to the roadside through automatic driving based on the travel environment information detected most recently before the acquisition failure and the travel information, and activates the vehicle peripheral object detector and, when an object is detected on the periphery around the vehicle, executes the evacuation control.

A system includes an autonomous vehicle (AV) comprising a sensor, a control subsystem, and an operation server. The control subsystem receives sensor data comprising location coordinates of the AV from the sensor. The operation server detects an unexpected event from the sensor data, comprising at least one of an accident, an inspection, and a report request. The operation server receives a message from a user comprising a request to access particular information regarding the AV and location data. The operation server associates the AV with the user if the location coordinates of the AV match location data of the user. The operation server generates a ticket for the unexpected ticket. The operation server communicates the particular information to the user. The operation server provides instructions to be forwarded to the user based on a request from the user. The operation server closes the ticket if the unexpected event is addressed.

A method for controlling the operation of an automatic driving assistance system of a motor vehicle, which is designed for independent vehicle guidance. When at least one driving control takeover condition is met which brings about deactivation of the driving assistance system when driving control is taken over by the driver, at least one takeover request is output to the driver. If the driver does not react to this takeover request, replanning of the original route occurs with an original destination to a stopping point which can be approached in an automated manner. The replanning occurs in such a way that the stopping point constitutes, in the context of the present position of the motor vehicle with respect to the original destination, an optimum stopping point which is determined according to at least one optimality criterion.

A driving control system includes an automatic driving control device and a driver monitoring device. The automatic driving control device includes a driver state determining unit, an override detector, a retreat mode controller, and a retreat mode canceler. During traveling under an automatic driving mode, when the driver state determining unit determines from a driver state detected by the driver monitoring device that the driver is not in a state capable of driving normally, the retreat mode controller sets a retreat mode in which an override operation is disabled and an own vehicle is caused to travel for retreat. When the driver state determining unit determines, during traveling for retreat, that the driver has returned to the state capable of driving normally, the retreat mode canceler cancels the retreat mode, and enables detection of the override operation of the driver by the override detector.

A modular vehicle subassembly includes a frame assembly with wheels and a steering system configured to steer at least one of the wheels and change a course of direction of the frame assembly. A propulsion system configured to drive at least one of the wheels and move the frame assembly in at least one of a forward direction and a backward direction is included. At least one transient data sensor, an onboard controller, and an onboard communications link are included and the least one transient data sensor is coupled is configured to detect and transmit transient data. The onboard controller is configured to receive the transient data from the at least one transient data sensor, direct the steering system and the propulsion system such that the frame assembly moves along a predefined path through a flexible modular platform facility.

A road information exchange system includes a plurality of Guided Autonomous Information Network (GAIN) units (102) installed on a road. Each GAIN unit (102) communicates with another GAIN unit (102) of the plurality of GAIN units (102) to divide the road into virtual lanes by formation of microgrids and further communicates with a vehicle passing through the road information exchange system (100).

The present disclosure relates to an Information processing apparatus, an information processing method, and a program for detecting a driver's abnormal physical condition during driving to implement processing in consideration of safety.

Vital data of the driver of a vehicle is acquired and the vehicle is controlled to a safe state according to an automatic driving level in a case where a determination result that an abnormal physical condition is occurring in the driver is acquired on the basis of the vital data. The present disclosure can be applied to an in-vehicle system.

Micro-authorization of remote assistance for an autonomous vehicle is described herein. A constraint that inhibits propulsion by a mechanical system of the autonomous vehicle is activated by a computing system of the autonomous vehicle, wherein a signal that identifies the activated constraint is transmitted from the autonomous vehicle to a remote computing system. The remote computing system generates instructions to deactivate the activated constraint. A return signal is transmitted from the remote computing system that specifies instructions to deactivate the constraint and a distance to desirably advance the autonomous vehicle. The computing system of the autonomous vehicle deactivates the constraint and the mechanical system is controlled to advance the autonomous vehicle when signal latency is less than a predetermined threshold duration of time.

A method is disclosed for improving the permissiveness of a vehicle designed to operate within an operational design domain (“ODD”) where the vehicle has an autonomous vehicle control system capable of collecting sensor data. The method, which can be incorporated into a system or into instructions placed on storage media, includes partitioning the ODD into subsets (“micro-ODDs”) that relate to different operational situations and creating safety envelopes for those subsets. The safety envelopes are used to keep the vehicle operating safely and can be optimized to improve permissiveness of the vehicular operation.