Aspects of the technology relate to assisting a passenger in an autonomous vehicle without a driver. For instance, after a door of the vehicle is opened, a predetermined period of time may be waited by processors of computing devices of the vehicle. After waiting the predetermined period of time and when the vehicle's door remains open, a set of instructions for closing the vehicle's door may be played by the processors through a speaker of the vehicle. Once the door of the vehicle is closed, an announcement may be played by the processors through the speaker requesting that the passenger press a first button to initiate a ride to a destination. In response to the first button being pressed, the ride to the destination may be initiated by the processors by maneuvering the vehicle autonomously to the destination.

A surrounding situation display method of detecting a surrounding situation around a host vehicle with an autonomous driving function and displaying the detected surrounding situation, includes displaying, in a varying display bar that has a prescribed display frame and displays an indication position within the display frame in synchronization with movement of an attention target, the indication position having moved to one endpoint of the varying display bar as a timing when an action of the host vehicle is changed by the autonomous driving function.

A vehicle control system includes an external environment recognition unit configured to recognize an external environment situation, an automated driving control unit configured to perform automated driving for automatically controlling at least one of acceleration/deceleration and steering of a subject vehicle, the automated driving control unit executing handover to switch a driving mode from an automated driving mode to a manual driving mode on the basis of the external environment situation recognized by the external environment recognition unit, a handover prediction unit configured to predict a possibility of occurrence of the handover on the basis of the recognized external environment situation, an output unit configured to output information, and an interface control unit configured to control the output unit so that information for prompting the vehicle occupant to prepare for the handover is output when the handover prediction unit predicts that the possibility of occurrence of the handover is high.

During a journey using a motor vehicle, a virtual environment is displayed by use of a display device and additionally a virtual representation of a route layout located in front of the motor vehicle is also displayed by use of the display device within the virtual environment. The display device may be used in the motor vehicle.

In one embodiment, an autonomous vehicle includes a controller and a control interface disposed in an enclosure on the side of the autonomous vehicle. The control interface includes a display communicatively coupled to the controller. The display is used to at least setup or control operation of an implement attached to the autonomous vehicle, setup or control operation of the autonomous vehicle, or both.

A head-up display apparatus is mounted on a vehicle having a plurality of driving modes with different degrees of automation and is configured to display a predetermined content in a predetermined display region provided in front of a driver seat. The head-up display apparatus is configured to display different contents depending on the plurality of driving modes.

A method for automatically parking a vehicle in a parking slot involves manually driving the vehicle into the parking slot in a training step, and thereafter automatically driving the vehicle into the parking slot in a replay step. Automatically driving the vehicle into the parking slot involves detecting information of features of the environment of the vehicle corresponding to the driven trajectory, matching feature descriptors of the detected features of the environment with feature descriptors stored in the digital map, and re-localizing the vehicle against the trajectory stored in the digital map in order to navigate the vehicle along the stored trajectory into the parking slot. Automatically driving the vehicle into the parking slot is repeated multiple times, and involves deleting a feature descriptor stored in the digital map if the number of matches does not exceed a threshold after a predefined number of repetitions.

A control device is intended to be embedded in a motor vehicle including a passenger compartment and at least one passenger service equipment item. The control device is provided to be coupled to each passenger service equipment item and includes a detection module configured to detect at least one passenger in the passenger compartment, a classification module configured to classify the detected passenger in at least one passenger category, and a generating module configured to generate, as a function at least of said passenger category, a command of the at least one passenger service equipment item.

Aspects of the technology relate to assisting a passenger in an autonomous vehicle without a driver. For instance, after a door of the vehicle is opened, a predetermined period of time may be waited by processors of computing devices of the vehicle. After waiting the predetermined period of time and when the vehicle's door remains open, a set of instructions for closing the vehicle's door may be played by the processors through a speaker of the vehicle. Once the door of the vehicle is closed, an announcement may be played by the processors through the speaker requesting that the passenger press a first button to initiate a ride to a destination. In response to the first button being pressed, the ride to the destination may be initiated by the processors by maneuvering the vehicle autonomously to the destination.

Techniques are disclosed for creating and presenting a graphical user interface for display of autonomous vehicle behaviors. The techniques include determining a trajectory of a vehicle operating in a real-world environment. Sensors of the vehicle obtain sensor data representing an object in the real-world environment. A maneuver of the vehicle to avoid a collision with the object is predicted based on the sensor data and the trajectory of the vehicle. It is determined that a passenger comfort level of a passenger riding in the vehicle will decrease based on the maneuver of the vehicle. The passenger comfort level is measured by passenger sensors of the vehicle. A graphical user interface is generated including representations of the vehicle, the object, and a graphic, text, or a symbol alerting the passenger of the predicted maneuver. The graphical user interface is transmitted to a display device of the vehicle.