A vehicle is configured to be charged with power supplied from the outside. The vehicle includes a storage battery, an interface configured to present a driver with power information on a state of charge of the storage battery, a monitoring device configured to monitor the driver and detect a confirmation operation of the driver for the interface, and a control device configured to complete, when the state of charge of the storage battery reaches a predetermined value during charging, the charging. The control device determines the predetermined value based on the state of charge of the storage battery calculated according to a detection frequency of the confirmation operation by the monitoring device.

Systems and methods for identifying available charging stations (e.g., charging stations available to be used by an electric vehicle) and/or determining travel routes for electric vehicles are described. In some embodiments, the systems and methods receive a request to find an available charging station, determine a state of charge for an electric vehicle associated with the request, identifies one or more available charging stations located within a suitable distance to the electric vehicle, the suitable distance based on the determined state of the charge for the electric vehicle, and present information to the electric vehicle, or an associated mobile device, that indicates the identified charging stations.

A capacity control device including: a storage unit for storing information representing a first energy amount and a second energy amount of an amount of energy accumulated in a power source for driving mounted on a vehicle, the first energy amount being available for power transmission and reception between the power source for driving and a power grid without an instruction from a user of the vehicle, and the second energy amount being available to the user in response to an instruction from the user; a updating unit for updating the second energy amount without updating the first energy amount, and updating the first energy amount without updating the second energy amount; and a control unit for presenting information representing the second energy amount that has been updated by the updating unit to the user.

A method of controlling a drone positioned in a vehicle includes: determining the initial condition of the drone positioned inside the vehicle, releasing locking of the drone upon receiving a user request from a vehicle controller, receiving vehicle state information from the vehicle controller by a drone controller, performing flight of the drone in response to the user request, and after completing the user request, returning the drone to an initial position thereof.

A control device is a control device of a moving body that includes a first accumulation unit configured to accumulate first energy, a second accumulation unit configured to accumulate second energy different from the first energy, and an electric motor configured to generate power to move using any one or both of second energy obtained by converting first energy accumulated in the first accumulation unit and second energy accumulated in the second accumulation unit, in which a required amount, which is an amount of the second energy required to move from a current place to a supply point that is a point where supply of the first energy is received, is acquired when the second energy is accumulated in the second accumulation unit and, if the required amount has been supplied to the second accumulation unit, a termination-related operation related to termination of the supply is executed.

An electrified vehicle may include an electric motor coupled to a battery to propel and brake the vehicle, a pedal generating a pedal position signal including a released position signal, friction brakes configured to provide a stopping force to vehicle wheels, and a controller programmed to control the motor and the brakes in response to the pedal being released to decelerate the vehicle to a stop, and to control the motor and an engine (in hybrid vehicles) to inhibit propulsive torque to the wheels after stopping due to the pedal released position until receiving driver input indicative of a request for moving the vehicle, such as depressing the brake or accelerator pedal, or activating an automated vehicle maneuver, such as a parking maneuver, cruise control, or stop-and-go control. Inhibiting torque may include inhibiting creep torque and/or operating the electric machine to charge the battery when the engine is running.

The techniques described herein relate to a motor vehicle, including: a battery pack electrically connected to an electric machine and a plurality of electrical loads, wherein the motor vehicle is operable in a full power mode in which power can flow from the battery pack to the electric machine and each of the plurality of electrical loads, and a battery save mode in which a flow of power is prevented between the battery pack and either or both of the electric machine or at least some of the plurality of electrical loads; and a controller configured to command the motor vehicle to operate in the battery save mode if the motor vehicle has been parked in a known extended parking location for a first time period, or if the motor vehicle has been parked in a location other than a known extended parking location for a second time period longer than the first time period.

Methods and systems for activating electric vehicles are provided. One method includes, in response to a first command to activate the vehicle, transitioning the vehicle from an inactive state to a wake state where a controller of the vehicle is activated and the vehicle is prevented from being propelled by an electric motor of the vehicle. The method also includes, in response to receiving a second command to activate the vehicle after receiving the first command, transitioning the vehicle from the wake state to a ready state where the vehicle is permitted to be propelled by the electric motor.

Methods and systems are provided for controlling a high power output direct current to alternating current converter for a vehicle. In one example, a method may include at a vehicle-on event, automatically operating the converter in a first power output mode, and transitioning to a different mode of operation in response to a transition request being received at a controller of the vehicle. In this way, the different mode of operation may be subject to confirmation via an operator of the vehicle, which may improve operational performance of the direct current to alternating current converter.

Methods and systems for activating electric vehicles are provided. One method includes, in response to a first command to activate the vehicle, transitioning the vehicle from an inactive state to a wake state where a controller of the vehicle is activated and the vehicle is prevented from being propelled by an electric motor of the vehicle. The method also includes, in response to receiving a second command to activate the vehicle after receiving the first command, transitioning the vehicle from the wake state to a ready state where the vehicle is permitted to be propelled by the electric motor.