Provided is a control device for controlling a flight vehicle including a battery; and an antenna for forming a communication area on the ground to provide wireless communication service for a user terminal in the communication area by using electric power of the battery. The control device comprises a control unit for performing control so as to reduce the number of cells included in the communication area when a predetermined condition is satisfied while the flight vehicle forms the communication area including a plurality of cells to provide wireless communication service for the user terminal.

This invention provides for a multi-disciplinary energy harnessing mechanism for outfitting a vehicle. Accordingly, sub-systems for harnessing energy from various sources of renewable energy occurring in vicinity of/incidental to the vehicle, such as 5 solar, waste heat, miming water, flowing wind, mechanical impacts, heat from the road surface being traversed are integrated into a vehicle whereby the effective range of the vehicle is increased while reducing the frequency and amount of charging otherwise required from the electric grid.

A system includes processor. The system includes a memory, the memory storing instructions executable by the processor to identify, in a vehicle at a first location, a second location receiving reflected light. The memory stores instructions executable by the processor to navigate the vehicle from the first location to the second location receiving the reflected light.

A system for managing heat in a mobile charger configured to provide power to an electric vehicle includes the mobile charger. The mobile charger includes a fuel cell stack, a heat reservoir, and a liquid coolant system including one or more liquid coolant loops configured to transfer heat between the fuel cell stack and the heat reservoir. The mobile charger further includes a computerized processor which is programmed to selectively control the liquid coolant system in one of a plurality of a thermal management modes configured to selectively remove heat from the fuel cell stack and provide heat to the fuel cell stack.

A method for determining the absolute position of a vehicle for the close-range positioning of same when the vehicle is being parked is described. An inductive positioning method is performed, wherein a first transmitter in the infrastructure or in the vehicle is excited to generate a positioning magnetic field and a second transmitter in the infrastructure or in the vehicle is excited to generate a positioning signal. The positioning magnetic field and the positioning signal are received by a reception device in the vehicle or in the infrastructure and the received positioning magnetic field and positioning signal are taken as a basis for ascertaining the absolute position of the vehicle. This allows particularly exact parking of the vehicle, in particular of an electrically operated vehicle for inductive charging.

A monitor device is provided with an imaging device that shoots an overhead line and a current collector, and a controller that processes an image. The controller includes a day or night determination processing section, and an image processing section that switches a parameter for recognizing the overhead line and the current collector in the image by executing image processing different in the daylight and at night based upon the result of the day or night determination. Further, there are provided reference photographic subjects to be shot by the imaging device in positions different from the overhead line and the current collector in an image area to be shot, and the day or night determination processing section performs the determination of day or night based upon a luminance average value of the reference photographic subjects inputted into an image input section.

Systems and methods for enabling fast charging of an electric vehicle at a charging station. An electric vehicle in positioned in a given location for charging and/or discharging. A charging arm comprising a plurality of charging brushes is then positioned relative to the position of the electric vehicle. The plurality of charging brushes on the charging arm is positioned to contact a charging interface of the electric vehicle. The charging brushes are moved relative to the charging interface such that a portion of the charging brushes is removed as a result of the movement.

A method for calculating a distance to empty (DTE) of an eco-friendly vehicle is provided. The method includes determining a travel route along which the vehicle travels to a received destination, estimating cooling power consumption for cooling a battery by reflecting travel information predicted for the determined travel route, and calculating the DTE by reflecting the estimated cooling power consumption.

An energy management system for an electric autonomous vehicle comprises a battery and a controller comprising a processor and a non-transitory computer-readable medium. The system comprises a pre-allocation input mechanism transmitting an input signal to the processor relating to a travel destination for the vehicle. The system comprises a navigation module receiving a wireless signal from a satellite network relating to a current location of the vehicle. The system comprises an autonomous input mechanism powered by the battery and transmitting an autonomous signal to the processor relating to dynamic conditions for autonomous operation of the vehicle. The processor determines a route between the current location and the travel destination, performs autonomous operation of the vehicle along the route, and selectively powers or tunes the usage of the at least one autonomous input mechanism with the battery during autonomous operation of the vehicle.

A method for a light electric vehicle that supports a weight of a user that includes the steps of supplying a support surface to support the weight of a user; supplying a motor controller containing a processor to control operation of an electric motor mounted i) on the support surface, or ii) proximal to the support surface, where the motor controller and its processor are electrically connected to the rechargeable electric battery, where the electric motor is electrically connected to the motor controller and the rechargeable electric battery, as well as connected to a drive mechanism to drive one or more wheels; and supplying a mode selector to set a first riding-experience mode for the light electric vehicle, wherein the first riding-experience mode has a first acceleration maximum and a second riding experience mode has a second acceleration maximum.