Routes may be presented to a vehicle operator with information about predicted autonomous driving levels. A road network route to a destination is received. The road network route is partitioned into segments. Indicia of the segments are provided to an inference engine. The inference engine predicts levels of autonomous driving for the respective segments generated by the inference engine based on the indicia of the segments. Based on the predicted levels of autonomous driving for the respective segments, a ratio of a level of autonomous driving for the road network route is computed. The ratio corresponds to a proportion of time and/or distance for the road network route during which a driver-system is predicted to be engaged at the level of autonomous driving. A user interface is displayed, which includes a graphic representation of the road network route and a graphic indication of the ratio.

In one embodiment, a method of controlling adaptive window transparency includes calculating a buffer period having a start time and an end time. The method also includes adjusting transparency on a set of windows based on the start time of the buffer period and transferring control of the vehicle to the vehicle or driver based on the end time. In response to detecting an emergency, the method further includes removing all tinting on the set of windows. In another embodiment, a method of controlling adaptive window transparency includes calculating a buffer period based on a navigation route.

A vehicle controller includes a memory configured to store map information including information on a predetermined area used in autonomous driving control of a vehicle; and a processor configured to: refer to the map information to identify an autonomous-driving practicable point at which a planned travel route from the current position of the vehicle outside the predetermined area to a destination of the vehicle enters the predetermined area, calculate a manual-driving section length from the current position of the vehicle to the autonomous-driving practicable point along the planned travel route, and notify the calculated manual-driving section length to a driver of the vehicle via a notification device provided in the interior of the vehicle.

A driving handover system according to the present disclosure is configured to execute a detection process of detecting an obstructive article that causes an obstruction of handover to manual driving when the obstructive article is present in a vehicle, and a determination process of determining whether the handover to the manual driving is allowed or disallowed upon receipt of a request for the handover to the manual driving. The driving handover system is configured to, in the determination process, disallow the handover to the manual driving when the obstructive article is detected in the detection process.

A remote support system facilitates assignment of vehicles to remote support agents for providing teleoperation or other remote support services. The remote support system may generate assignments based on a mapping function that optimizes various parameters based on sensed data associated with the vehicle, a requested service mode of the vehicle, or other factors. In some situations, the remote support server assigns a redundant set of remote support agents to a vehicle that provide similar command streams. The vehicle selects between the command streams to minimize latency or another performance parameter. Alternatively, the remote support server assigns multiple diverse remote support agents to a vehicle that generate diverse command streams. A proxy agent then generates a consensus command stream for providing to the vehicle.

A control device for an automated driving vehicle has a first automated driving mode in which the automated driving vehicle, receiving a permission notice from an operations management controller, travels, according to automatic operation, along a controlled route managed by the operations management controller, in accordance with a traveling schedule provided from the operations management controller; and a second automated driving mode in which the automated driving vehicle travels, without a permission notice from the operations management controller, along a non-controlled route that is not managed by the operations management controller, according to automatic operation. The first automated driving mode and the second automated driving mode are switchable.

An accelerator pedal system includes a pedal lever, a lock mechanism, an actuator, and an ECU. The lock mechanism can restrict the operation of the pedal lever. The actuator switches between a locked state in which the operation of the pedal lever is restricted by the lock mechanism and an unlocked state in which the operation of the pedal lever is not restricted. The ECU includes a lock operation determination unit and an actuator control unit. The lock operation determination unit resumes the locked state by the drive of the actuator after a release from the locked state due to the step-on operation of the pedal lever during the automatic drive control in the locked state, when (i) the automatic drive control is continued or (ii) a resuming of the automatic drive control is detected.

A driving support device is provided which can efficiently perform training for driving support. A driving support device (11) is equipped to a vehicle (1), and includes a driving support execution unit (201) capable of executing driving support to control steering and/or braking of the vehicle 1, and executing the driving support when the driver of the vehicle (1) performs a predetermined operation using a predetermined operator provided in the vehicle (1); and a driving support training control unit (202) which executes driving support training processing for the driver of the vehicle (1) to train the predetermined operation, in which the driving support training control unit (202) executes the training support training processing after the vehicle (1) has started up and during vehicle stop.

A control device controls a vehicle including a seat suspension which is provided between a chassis and a seat of the vehicle and restricts vibration and of which each of a spring constant and a damping coefficient is changeable and controllable. The control device detects, as vehicle information, a vehicle speed, an acceleration, a state of acceleration operation by a driver, a state of deceleration operation by the driver, and a state of steering by the driver. The control device determines, based on the vehicle information, whether the driver has driving preference of emphasizing the steering stability performance of the vehicle or driving preference of emphasizing the ride comfort performance of the vehicle, and, according to the determined driving preference, changes an acceleration of the seat by controlling the seat suspension.

A vehicle driving control system has an automatic driving mode for automatic driving. The system includes a driver monitor, a driver abnormal state detector, a risk state detector, and an alarm controller. The driver monitor monitors, as a driver, an occupant in a vehicle compartment that can take over driving from the system during the automatic driving mode. The driver abnormal state detector detects an abnormal state of the driver based on a monitoring result by the driver monitor. The risk state detector detects, as a risk state, at least one of a control state or a traveling environment of the vehicle in the automatic driving mode. The alarm controller controls an alarm to be output to the driver during traveling in the automatic driving mode based on at least the risk state out of the abnormal state of the driver and the risk state of the automatic driving mode.