An electric vehicle, and a system and method for charging the electric vehicle. The system includes a user locating system and a processor. The user locating system is configured to determine a location of the user. The processor is configured to charge the vehicle at a first charging rate and determine a location of a user of the vehicle with respect to the vehicle. The processor adjusts the charging of the vehicle from the first charging rate to a second charging rate when the location of the user is within a selected distance from the vehicle.

A method for controlling an electric vehicle and the electric vehicle are provided. The method includes: under a condition in which the electric vehicle is in unlocked and motor control shielded states, first predetermined information is detected, wherein the first predetermined information is used for indicating that a rider is located on the electric vehicle; the electric vehicle is controlled to switch from the motor control shielded state to a motor control unshielded state; a predetermined control signal is received in the motor control unshielded state; and a motor of the electric vehicle is controlled to rotate according to a rotational speed corresponding to the predetermined control signal. With the disclosure, the problems of complex operation and poor user experience of a manner for controlling the electric vehicle in the related art are solved.

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 personal mobility includes first and second test voltage sources, first and second switches, a ground, a first sensor, a second sensor obtaining weight information of a user, and a controller to: based on startup of the personal mobility, measure a first voltage applied to the first switch provided between the first test voltage source and the ground through the first sensor and a second voltage applied to the second switch provided between the second test voltage source and the ground, assign the user to one of predetermined groups based on the weight information, and based on a case in which at least one of the first or second voltage is greater than or equal to a reference value by comparing the first and second voltages with the reference value previously allocated to a group to which the user is assigned among the plurality of predetermined groups, control alarm device to provide a warning alarm to the user.

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.

This disclosure relates to electrified vehicle charging systems that are equipped with multiple charging interfaces. An exemplary charging system may include a first charging interface, a second charging interface, an on-board charger module operably coupled to the first and second charging interfaces, and a control module configured to command the second charging interface to be isolated from the on-board charger module in response to a status change of a door of the first charging interface. The status of the door may be monitored by a sensor system of the charging system for determining whether or not to disable the second charging interface.

A moving object includes: a contact power receiver connected to an external contact power feeding device and configured to receive power from the external contact power feeding device; a non-contact power receiver configured to receive power from an external non-contact power feeding device in a non-contact manner; a detector configured to detect a state of an occupant boarding the moving object; and determination circuitry configured to determine which of the contact power receiver and the non-contact power receiver is utilized to receive the power based on the state of the occupant.

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.

Methods and systems are provided for adjusting a height of an electric vehicle with an adjustable suspension system. In one example, a method comprises: during a vehicle stop event, adjusting a height of a skateboard frame of an electric vehicle via an adjustable suspension system, based on at least one sensor input indicative of a desired skateboard frame height. In this way, user activities, including loading and unloading, may be facilitated.

A vehicle control device for a vehicle includes a processor. The vehicle includes a first battery, a second battery, an auxiliary load powered by the second battery, and a DC-to-DC converter configured to supply electric power from the first battery to either the second battery or the auxiliary load, or to both of the second battery or the auxiliary load. The processor is configured to: determine the state of a start switch and the boarding state of the vehicle; acquire the voltage of the second battery; and when the processor determines that the vehicle is in a non-started on-board state, determine based on the voltage of the second battery an order in which the DC-to-DC converter and the auxiliary load are driven. The non-started on-board state is a state in which the start switch is off and a user is presumed to be in the vehicle.