Systems and methods are configured for coordinating and providing passthrough charging during bidirectional energy transfer events between two or more electrified vehicles. The ability to pass charging power from one vehicle to another allows for multiple vehicles to be concurrently charged from a single charge source. Various passthrough charging strategies may be achieved with the proposed systems, including but not limited to, a distributed charging strategy, a waterfall charging strategy, a targeted charging strategy, an automated charging strategy, a pay-for-use charging strategy, etc.

Electric vehicle charging management methods and systems capable of integrating multiple identities are provided. First, a mobile device executes an application, and selects a first identity account from a plurality of identity accounts through the application. Then, a first charging request is generated according to the first identity account and a first charging station, and the first charging request is transmitted to the server via a network through the mobile device or the first charging station. In response to the first charging request, the server instructs the first charging station to perform a first charging operation via the network. Thereafter, the server continuously obtains first charging state information of the first charging operation from the first charging station via the network, and calculates a first charging fee associated with the first identity account based on the first charging state information.

A system for configuring an Electric Vehicle (EV) charging infrastructure, the apparatus comprising. The system receives user direction and inputs regarding a custom EV charging infrastructure, submits the data an optimal planning module which is configured for performing optimization based on objectives in view of a set of constraints; and generates a recommendation from the optimal planning module for a custom EV charging infrastructure based on charging needs and behavior of the consumers toward deferring upgrades in electric infrastructure without compromising energy required for electrical transportation. The system validates the results from the optimal planning module using discrete event-based simulator and generates charging schedules from the controlling module for custom EV charging based on information about EV data, distributed energy resource (DER), and the electric infrastructure without compromising energy required for electrical transportation and causing undue impact on the electrical infrastructure.

A multifunction electric vehicle charging platform is provided. The platform includes a housing and at least one display unit placed in the housing. The platform further includes a content management unit configured to control receiving content and display the content on the at least one display unit. The platform includes a charging unit configured to be connected to at least one light electric vehicle (LEV) and to provide power to the at least one LEV. The platform includes at least one sensor attached to the housing and configured to collect data associated with the at least one LEV. The platform further includes a communication unit configured to communicate with a backend system.

A battery data management method for use in a battery data management system including an electric vehicle and a plurality of authentication servers each including a distributed ledger includes: obtaining, by the electric vehicle, first sensor information about a battery attached to the electric vehicle; generating, by the electric vehicle, first transaction data including the ID of the battery and the first sensor information; obtaining the first transaction data by one authentication server included in the plurality of authentication servers; and recording a block including the first transaction data into the distributed ledger by the one authentication server.

Method and apparatus for power mode control for electric propulsion vehicles are provided that include a sensor to detect a vehicle door cycle, a processor to establish an occurrence of a vehicle motion, a processor operative to initiate a timer having a default time duration in response to the occurrence of the vehicle motion and the vehicle door cycle and to generate a user prompt to extend the default time duration, the processor being further operative to transition an operating mode to a shutdown mode in response to an expiration of the time, and to extend to the default time duration in response to the user input, and a display operative to display a user interface in response to the user prompt and to receive a user input indicative of a request to extend the default time duration of the timer and to couple the user input to the processor.

A method and apparatus for parking lot metering. The present invention allows multi-space meters to separately manage and control premium parking spaces, such as those for charging electric vehicles or those which supply electric power for engine block heaters in both pay-by-space and pay-and-display systems. Such premium spaces can be managed together over large areas (e.g., a city or region), or may be managed over smaller areas (e.g., the domain of an individual kiosk), or individually per parking space. Management includes pricing, time limits, hours, seasons of operation, and restrictions by vehicle type, and alternative pricing and restrictions for non-premium hours.

A vehicle includes a power unit, wherein the power unit includes an internal combustion engine and/or a power battery. The vehicle is provided with a living room mode, which can be activated in a parking state of the vehicle. When the living room mode is activated, the power unit of the vehicle can provide the vehicle with functions related to leisure, entertainment and/or office, but does not provide functions related to drive readiness.

Methods and systems for communicating with a server of a cloud services system used to interface with vehicles are provided. One method includes receiving, by the server, a request from electronics of a vehicle to access a profile for a user account. The request identifies user information for a user to use the vehicle. The method includes processing, by the server, at least part of the user information to verify the user against data associated with the user account. The profile has a plurality of settings of the user for the vehicle, and at least part of the plurality of settings for the profile being stored on storage accessible to the cloud services system. The method includes transferring, by the server, upon verification of the user information, one or more settings of the plurality of settings to the vehicle. The transferring is configured to instruct software associated with said electronics of the vehicle to apply said one or more settings to the vehicle for customizing said vehicle to use said one or more settings, and the vehicle uses wireless communication with the cloud services system to receive said one or more settings for the profile. And, the profile is transferrable from vehicle to vehicle used by the user, so user settings go with the user. The profile, in one example, is activated automatically in a vehicle upon pairing a device with the vehicle.

A robot for charging a vehicle is provided. The robot has wheels or configured for a track for the robot to automatically move to the vehicle to provide charge to a battery of the vehicle. A charge storage is associated with the robot. An articulating arm of the robot. The articulating arm is configured for movement that enables the articulating arm to automatically connect to a connector of the vehicle after the robot moves in position beside the vehicle for providing charge to the battery of the vehicle.