A management device includes an information acquirer configured to acquire battery information on a usage state of a secondary battery mounted in a vehicle and information on a user from the vehicle, a first feature deriver configured to derive a first feature indicating a state of the secondary battery based on a result obtained by applying the battery information to a battery state detection model that identifies the state of the secondary battery, a second feature deriver configured to derive a second feature indicating characteristics of the user based on the information on the user, and a selector configured to select a battery suitable for the user based on a result obtained by inputting the first feature and the second feature to a matching model that outputs a result showing compatibility between the user and a battery based on the first feature and the second feature.

A charging station for an electric vehicle determines that a first person is in proximity to the charging station and identifies whether the first person is a user of the charging station. In accordance with a determination that the first person is a user of the charging station, the charging station provides, using a first mode for selecting content for users of the charging station, first content for display. The charging station determines that a second person is in proximity to the charging station and identifies whether the second person is a user of the charging station. In accordance with the determination that the second person is not a user of the charging station, the charging station provides, using a second mode for selecting content distinct from the first mode for selecting content, second content for display. The second mode provides content for non-users of the charging station.

A vehicle control device includes a recognition unit that recognizes a surrounding situation of a vehicle, and a driving control unit that controls one or both of steering or acceleration and deceleration of the vehicle based on the surrounding situation recognized by the recognition unit. The driving control unit determines whether or not an occupant is riding in the vehicle, and differentiates a road on which the vehicle is caused to travel, between a case where it is determined that the occupant is riding in the vehicle and a case where it is determined that the occupant is not riding in the vehicle.

An apparatus comprising an interface, a memory and a processor. The interface may be configured to receive sensor data samples during operation of a vehicle. The memory may be configured to store the sensor data samples over a number of points in time. The processor may be configured to analyze the sensor data samples stored in the memory to detect a pattern. The processor may be configured to manage an application of brakes of the vehicle in response to the pattern.

Systems and methods are provided herein for identifying the status of an electric vehicle charging station’s (EVCS) parking space. This may be accomplished by an EVCS detecting an electric vehicle in a parking space using one or more sensors. The EVCS can use the one or more sensors to receive user information relating to the detected electric vehicle. The EVCS can then determine a status (e.g., “Occupied,” “Soon to be occupied,” “Available,” “Soon to be available,” etc.) of the parking space using the received user information. The EVCS then transmits the status to a device (e.g., server, smartphone, etc.).

A vehicle battery heating apparatus is to be mounted in a vehicle that travels with electricity from a battery. The apparatus includes a battery, a heater, a sensor, a controller, and a memory. The battery is mountable in the vehicle to allow the vehicle to travel. The heater heats the battery. The sensor obtains a temperature of the battery. The controller heats the battery with the heater. The memory stores heating target temperatures for respective remaining capacities of the battery. The controller obtains a remaining capacity of the battery, obtains a target temperature from the memory in accordance with the obtained remaining capacity, and sets a target temperature for heating the battery which is not on charge while the vehicle is stopped to the obtained target temperature. The heater heats the battery to the set target temperature.

The present application relates to the field of automotive technologies, and provides an electric vehicle wireless charging method, an apparatus, and a system. A wireless charging station can charge an electric vehicle according to a charging request of the electric vehicle and charging permission of the electric vehicle prestored on the wireless charging station, so that resources of the wireless charging station are maximally used, and resource waste of the wireless charging station is avoided.

The invention relates to a system for charging and for holding a battery-powered vehicle (20, 30). The system comprises an adapter (4) for being mounted on the vehicle (20, 30), in particular for being mounted on a cylindrical handlebar (21, 31) of a two-wheeled vehicle, the adapter (4) comprising a charging apparatus (41) that corresponds to the charging device (11) and has a receiver coil, wherein, when the fastening device is open, the receiving region extends between its longitudinal ends in the longitudinal direction X over at least 3 cm, and the transmission coil has a cross-sectional area of at least 15 cm.sup.2, wherein the fastening device, when closed, sets the mobility of the holding portion to a holding tolerance range which is set in its transverse extension and in its longitudinal extension, wherein the charging device (11) and the charging apparatus (41) can be correspondingly designed in such a way that, when the charging apparatus (41) is situated relative to the charging device (11) within a position tolerance range, this allows electrical energy to be transmitted from the charging device (11) to the charging apparatus (41) with an efficiency of more than 80%.

Various example embodiments relate to managing charging stations of electric vehicles based on a proximity of a user. A beacon transmitter is configured to broadcast identifiers of a charging station and of a list of allowed users. A mobile device of the user is configured to detect a proximity of the beacon transmitter and determine if the charging station can be set for charging based on an identifier of the user, the identifier of the charging station and the identifier of the user list. Apparatuses, methods, and computer programs are disclosed.

Various disclosed embodiments include illustrative electrical power dispensers for electrical vehicle charging systems, charging systems, and methods of sensing presence of a charge coupler in a holster of an electrical power dispenser. In an illustrative embodiment, an electrical power dispenser for an electrical vehicle charging system includes a housing. A charge coupler is configured to dispense direct current electrical power. A holster is disposed on the housing and is configured to receive the charge coupler therein. A holster sensor is configured to sense presence of the charge coupler in the holster and is further configured to generate a signal indicative of presence of the charge coupler in the holster.