A vehicle includes two or more soft touch radio frequency (RF) antennas and two or more RF transceivers to communicate sensitive information associated with a user of the vehicle. A processor in communication with the two or more RF transceivers selects a first RF transceiver associated with the deployed RF antenna to send the sensitive information and sends the sensitive information to the first RF transceiver.

A system for controlling powertrain of an electric vehicle, comprising: a driver recognition module, configured for determining the identity information of the controlled vehicle's driver, and uploading the identity information to a backend computing unit; the backend computing unit, located at a remote end of the controlled vehicle, configured for generating a first control information based on the driver's identity information; an assist control module, configured for generating a second control information based on the information related to current driving of the controlled vehicle which is acquired from the backend computing unit; and a control information application module, integrated in the controlled vehicle, configured for applying the first and second control information to the powertrain of the controlled vehicle. Optimized control for powertrain is achieved and an excellent user experience is provided. The system can be implemented simply, and be updated and maintained conveniently.

A smart key device for use with a vehicle is disclosed. The smart key comprises: an interface configured to communicatively couple with a controller of the vehicle; and a non-volatile storage module configured to store a deactivation message configured to cause the controller of the vehicle to deactivate and/or limit the functionality of the vehicle. The deactivation message may include an indication of a time period or distance driven after which the vehicle will be deactivated. A vehicle controller; a smart key write device and associated methods are also disclosed.

According to one embodiment, managing power provided by a battery system can comprise receiving, by a controller of the battery system, a set of management rules defining conditions and actions for altering an allocation of power provided by one or more batteries of the battery system. The controller of the battery system can read a set of configuration information for the battery system. The controller of the battery system can additionally or alternatively read a set of use information for the power source from one or more databases. The controller of the battery system can then apply the management rules using the set of service configuration information and/or the set of use information. Based on applying the management rules, one or more characteristics of the power provided by the battery system can be altered by the controller of the battery system.

According to one embodiment, provisioning an amount of power for one or more vehicles can comprise receiving a request indicating a requirement for an amount of power for the one or more vehicles. The request can indicate the requirement for the amount of power for the one or more vehicles individually or in total. A set of management rules can be read from one or more databases. A set of service configuration information and a set of vehicle specific information for the one or more vehicles can also be read from one or more databases. One or more power sources to meet the requirement for the amount of power for the one or more vehicles can be determined based on applying the management rules and using the set of service configuration information and the set of vehicle information and an indication of the determined power sources can be provided.

According to one embodiment, controlling a battery-powered vehicle can comprise receiving, at a control system of the vehicle over a network connection, a first set of parameters. Each parameter of the first set of parameters can be directed to one or more of a plurality of aspects of operating a battery system of the vehicle. The control system of the vehicle can save the first set of parameters and apply the first set of parameters to operations of the vehicle. Applying the first set of parameters to operations of the vehicle can comprise controlling operations of the battery system of the vehicle to limit power available from the battery system of the vehicle based on the first set of parameters.

Systems of an electrical vehicle and the operations thereof are provided that use identifiers and sensed power source parameters to determine whether a rule, such as a warranty or licensing requirement, has been violated.

A vehicle is provided that detects a first presence of a driver in a vehicle, based upon detecting the first presence, provides a user interface for the driver to enter first user information, information, and communicates the first sensitive information to a vendor to authenticate the combines the first user information and the vehicle information to generate the first sensitive driver to enable the vendor to perform a financial transaction with the driver using the first sensitive information while the vehicle is in motion. The processor is programmed to initiate automatically, on behalf of the driver, the financial transaction with the vendor in response to a sensed state or location of the vehicle.

Systems of an electrical vehicle and the operations thereof are provided.

A method and system are provided for detecting a driver and passenger in a vehicle. The vehicle processor stores first and second sensitive information for the driver and passenger, respectively. In response to detecting the second presence of the passenger, provides a user interface for the passenger to enter the second sensitive information, receives and associates the second sensitive information with the vehicle and, while the vehicle is in motion, communicates with an external third party positioned along a selected route of the vehicle to perform a transaction on behalf of the passenger using the second sensitive information.