Apparatuses, systems, and methods are provided for the utilization of vehicle control systems to cause a vehicle to take preventative action responsive to the detection of a near short term adverse driving scenario. A vehicle control system may receive information corresponding to vehicle operation data and ancillary data. Based on the received vehicle operation data and the received ancillary data, a multi-dimension risk score module may calculate risk scores associated with the received vehicle operation data and the received ancillary data. Subsequently, the vehicle control systems may cause the vehicle to perform at least one of a close call detection action and a close call detection alert to lessen the risk associated with the received vehicle operation data and the received ancillary data.

A control system for a vehicle is provided. The system includes an automated driving control unit for performing driving control that is at least one of speed control and steering control of the vehicle, the control system comprises a detection unit configured to detect a state and an operation of an occupant, and a notification unit configured to notify the occupant of a change in what/who is to perform a driving operation, when travel control performed by the automated driving control unit is shifted to travel control performed according to manual driving, wherein the notification unit changes notification content stepwise in accordance with a change in at least one of the state and the operation of the occupant detected by the detection unit.

When an occurrence of override due to an acceleration/deceleration operation and/or a steering operation is detected by an acceleration/deceleration override detection unit and/or a steering override detection unit, a driving mode is switched by a mode switching unit to a semi-automatic driving mode in which the degree of automatic control is higher than when an occurrence of override due to the acceleration/deceleration operation and the steering operation is detected. According to this configuration, the degree of automatic control can be appropriately regulated in accordance with an override state, so a vehicular behavior not intended by the driver can be prevented. In addition, because the partial automatic control is maintained, the burden of driving can be reduced.

A vehicle control system includes an automated driving control unit that automatically controls at least one of acceleration/deceleration and steering of a subject vehicle, the automated driving control unit performing automated driving control in any one of a plurality of modes with different degrees of automated driving, and an interface control unit that receives an operation of an occupant of the subject vehicle and restricts an operation with respect to an interface device on which predetermined information is output, according to the mode of automated driving performed by the automated driving control unit, and when the change to the mode of the automated driving in which the degree of automated driving decreases is performed in a state in which the restriction is relaxed or released, the interface control unit causes a state of the interface device to return to a state before the restriction is relaxed or released or performs a predetermined notification before a predetermined time at which the change of the mode of the automated driving is performed.

A vehicle control apparatus comprises a periphery monitoring unit configured to be capable of detecting a front vehicle traveling in front of a vehicle, and a vehicle control unit configured to be capable of controlling the vehicle on the basis of a travel state of the vehicle or a travel state of the front vehicle. The vehicle control unit can carry out vehicle control in a first control state, as well as vehicle control in a second control state in which a level of autonomy of the vehicle control is higher or the extent to which a driver is required to contribute to vehicle operations is lower than in the first control state.

The present invention provides an automatic driving system capable of clearly identifying the factors responsible for causing an abnormality such as an accident or malfunction of a vehicle during automatic driving after the fact. The automatic driving system automatically selects, from each automatic driving function provided in the vehicle or each level of driving automation into which each automatic driving function is classified, an automatic driving function or a level of driving automation according to the circumstances surrounding the vehicle or the driving state of the vehicle, automatically performs a part of or the entirety of a vehicle driving operation to automatically drive the vehicle, and, remembers the time of automatic driving and information indicating the selected automatic driving function or level of driving automation at that time.

Systems and methods for controlling an autonomous vehicle are provided. In one example embodiment, a computer-implemented method includes receiving data indicative of an operating mode of the vehicle, wherein the vehicle is configured to operate in a plurality of operating modes. The method includes determining one or more response characteristics of the vehicle based at least in part on the operating mode of the vehicle, each response characteristic indicating how the vehicle responds to a potential collision. The method includes controlling the vehicle based at least in part on the one or more response characteristics.

A vehicle control device includes a takeover operation unit configured to execute operations whereby at least a portion of automated driving is handed over to manual driving performed by a driver, and a duration acquisition unit configured to acquire a duration of the automated driving when the at least a portion of the automated driving is handed over to manual driving performed by the driver. In the case that the duration is greater than or equal to a first predetermined time period, the takeover operation unit performs an operation to hand over driving to manual driving differently from an operation to hand over driving to manual driving in the case that the duration is less than the first predetermined time period.

Vehicle systems and methods for controlling a vehicle to mitigate the effects of an incapacitated driver are disclosed. In one embodiment, a vehicle includes one or more sensors, one or more processors, and one or more non-transitory memory modules communicatively coupled to the one or more processors. The memory modules store machine-readable instructions that, when executed, cause the one or more processors to receive one or more signals output by the one or more sensors and determine a driver of the vehicle is incapacitated based on the one or more signals output by the one or sensors. In response to determining the driver is incapacitated, the processors are caused to determine a specific type of incapacitation of the driver based on the one or more signals output by the one or more sensors. The processors may select an individual vehicle control profile based on the specific type of incapacitation.

A method for providing operating mode transition for a vehicle includes receiving an input indicating a request to transition from a first operating mode of the vehicle to a second operating mode of the vehicle and determining a first planned trajectory corresponding to the first operating mode. The method also includes determining a second planned trajectory corresponding to the second operating mode. The method also includes determining a first road wheel actuator angle corresponding to the first planned trajectory and determining a second road wheel actuator angle corresponding to the second planned trajectory. The method also includes determining a difference between a current handwheel actuator angle and a handwheel actuator angle corresponding to the second road wheel actuator angle and, in response to a determination that the difference is less than a threshold, transitioning from the first operating mode to the second operating mode over a determined period.