An automated valet parking (AVP) management system manages an AVP service delivered in a predetermined area. A pick-up or drop-off point is away from a parking facility in which a vehicle is parked. When it is not possible to deliver the AVP service to a user in accordance with a user request, notification information is delivered to the user. The notification information includes at least one of: a congestion situation on a route from a current position of the vehicle to a specified pick-up or drop-off point; a congestion situation at the specified pick-up or drop-off point; a waiting time for the user to get on or off the vehicle at the specified pick-up or drop-off point; a recommended time of day of use at the specified pick-up or drop-off point; and a substitute pick-up or drop-off point being a substitute for the specified pick-up or drop-off point.

A method for controlling an autonomous vehicle includes using one or more computing devices to transmit a request for a trip. The trip is from a pickup location to a destination location. The method also includes determining the autonomous vehicle for the trip is within a predetermined distance from the pickup location, providing a set of component controls to receive user input at a user interface after the determining. The set of component controls includes interactive controls for identifying or accessing the autonomous vehicle. A first user input is received at the user interface for one or more of the set of component controls, and control instructions for the autonomous vehicle based on the first user input are transmitted.

The technology involves to pickups performed by autonomous vehicles. In particular, it includes identifying one or more potential pullover locations adjacent to an area of interest that an autonomous vehicle is approaching. The vehicle detects that a given one of the potential pullover locations is occupied by another vehicle and determines whether the other vehicle will be vacating the given pullover location within a selected amount of time. Upon determining that the other vehicle will be vacating the given potential pullover location within the timeframe, the vehicle determines whether to wait for the other vehicle to vacate the given pullover location. Then a driving system of the vehicle either performs a first action in order to wait for the other vehicle to vacate the given pullover location or performs a second action that is different from the first action when it is determined to not wait.

According to one aspect, a method includes obtaining a request for a first vehicle from a customer, and dispatching the first vehicle to a first location identified in the request. Dispatching the first vehicle to the first location includes causing the first vehicle to drive in an autonomous mode. The method also includes determining when the first vehicle arrives at the first location, and providing the customer with access to enter the first vehicle.

A rideshare management system includes: a communicator configured to communicate with a plurality of terminal devices used by a plurality of users; an acquirer configured to acquire use requests from the plurality of users in which a use condition including at least a desired access place is defined; a user arrival situation monitor configured to monitor an arrival situation of the users at a predetermined place derived according to the desired access place; and a service manager configured to search for an available vehicle according to the use condition included in the use requests and determine a vehicle service schedule and configured to determine a user accessing the vehicle at the predetermined place according to the arrival situation of the users monitored by the user arrival situation monitor.

A system in facility includes a plurality of electric mobility vehicles, and a server which stores information of the electric mobility vehicles. In this system in facility, a user operates one of the electric mobility vehicles to move the electric mobility vehicle, after the user finishes using the electric mobility vehicle, the electric mobility vehicle moves to a standby area by automatic driving, and usage information of the electric mobility vehicle by the user is stored in a management data in a server, and at least one of a seating sensor for a seat unit and a occupancy sensor for a luggage carrier of the electric mobility vehicle is provided in each of the electric mobility vehicles.

Aspects of the disclosure provide for arranging trips for autonomous vehicles. For instance, a request for a trip may be received by one or more processors of one or more server computing devices. The request may identify an initial location. A weather condition at the initial location may be identified. One or more internal vehicle state conditions and one or more priorities for pulling over may be determined based on the weather condition. A second location may be determined based on the one or more priorities and the initial location. Dispatch instructions may be provided to an autonomous vehicle, the dispatch instructions identifying the second location and the one or more internal vehicle state conditions in order to cause computing devices of the autonomous vehicle to control the autonomous vehicle to the second location and adjust internal vehicle state conditions based on the one or more internal vehicle state conditions.

A method for controlling a vehicle includes identifying a user identity associated with a user riding in the vehicle, determining a destination associated with the user identity, creating a detection zone proximate to the vehicle when the vehicle is localized in a first drop-off location associated with the destination, causing a sensory system to identify a hazard within the detection zone and generate a localization of the hazard, determining that a first probability of realizing a risk associated with the hazard is less than a first probability threshold, and generating a vehicle door actuation that permits the user to exit the vehicle based on the first probability of realizing the risk.

Disclosed is an electronic device for a vehicle, including a processor acquiring image data acquired by a camera mounted in a vehicle, determining a riding intention of an outside person based on the location, posture, and gesture of the outside person detected from the image data, and generating a control signal to stop the vehicle based on the riding intention.

A stopping position control device according to an embodiment includes a sitting position specifying unit configured to specify a sitting position of a user who gets off a vehicle next, the vehicle being subjected to automatic driving control, and a stopping position determination unit configured to determine a stopping position of the vehicle, at which the user gets off the vehicle, corresponding to the sitting position of the user.