A terminal device is provided to output information about using a transport device for a travel to a destination, a vehicle communicating with the terminal device, a personal mobility device communicating with the terminal device, a method of controlling the terminal device, and a method of controlling the vehicle.

An apparatus for displaying environment-friendly vehicle information when power is supplied externally is provided. The apparatus includes an energy source residual amount measuring device that is configured to measure a current energy source residual amount and a per-time energy source consumption and a path generating device that is configured to set a path to a destination. A vehicle controller is configured to calculate a total power usable time period based on the energy source residual amount when a vehicle supplies electric power to the outside. The vehicle controller supplies electric power to the outside when the vehicle travels along the path and adjusts the supply based on the total power usable time period and the power supply allowable time period.

A vehicle reach area presentation device sets a unit area in which a start point exists as a start area among unit areas into which a region on map data is divided and extracts pieces of probe data including records of past travels within a certain range from the start area. The device sets the unit areas, including goal points recorded in the extracted pieces of probe data, as reach areas, calculates energy consumptions from the start area to the reach areas by using the pieces of probe data, and presents the reach areas to a user while changing display of the reach areas depending on the calculated energy consumptions.

Disclosed is a cooling system for a battery of a vehicle and a method for cooling the battery. A heat absorption member is attached to a terminal of battery cell of the battery for absorbing heat. A controller of the vehicle computes heat generation based on the driver's input about the vehicle's destination, controls the battery to limit its current output after temperature.

A control device for a hybrid vehicle, the hybrid vehicle including an internal combustion engine, an electric motor, and a battery, includes an electronic control unit configured to: i) set a target SOC which is a target value of an SOC of the battery when the hybrid vehicle arrives at a prescribed charging base; ii) when the hybrid vehicle is traveling outside the charging base, control output of the internal combustion engine and the electric motor such that the SOC at a time when the vehicle arrives at the charging base is the target SOC; and iii) estimate a charging possibility which is a possibility that the battery is charged with an external power source in the charging base when the hybrid vehicle arrives at the charging base, and set the target SOC lower when the estimated charging possibility is high than when the estimated charging possibility is low.

A system and method for presenting electric vehicle charging options that include determining a current geo-location of an electric vehicle and determining a current state of charge of a battery of the electric vehicle. The system and method also include determining at least one charging station that is within a remaining distance that the electric vehicle is capable of traveling based on the current geo-location of the electric vehicle and the current state of charge of the battery of the electric vehicle. The system and method further include presenting a charging station map user interface that pin points the current geo-location of the electric vehicle and the at least one charging station.

Disclosed herein a method for upshifting the transmission of a vehicle using shift entry prediction. The method may comprise predicting whether or not an upshift request of a vehicle will occur, determining whether or not a charge demand required for a battery through regeneration for upshift is greater than an allowable charge amount of the battery when the upshift request is predicted, controlling power consumption of the battery when the charge demand is greater than the allowable charge amount, and processing the upshift in response to an actual request of the upshift.

In one aspect, a system for charging an aircraft can include a robotic charging device, and a computing system configured to obtain data associated with a transportation itinerary and energy parameter(s) of the aircraft. The data associated with the transportation itinerary can be indicative of an aircraft landing facility at which the aircraft is to be located. The computing system can determine (e.g., select) a robotic charging device from among a plurality of robotic charging devices for charging the aircraft based on the transportation itinerary data and energy parameter(s) of the aircraft; determine charging parameter(s) for the robotic charging device based on the transportation itinerary data; and communicate command instruction(s) for the robotic charging device to charge the aircraft according to the charging parameter(s). The robotic charging device can be configured to automatically connect with a charging area of the aircraft for charging a battery onboard the aircraft.

A method for determining a minimum state of charge for an energy storage means of a vehicle can include: determining a routine of use of charge of the energy storage means; determining a user requirement for future driving of the vehicle; predicting a reduction in the state of charge of the energy storage means associated with the user requirement in dependence on the determined routine; determining a minimum state of charge for the energy storage means for enabling the user requirement to be satisfied in dependence on the predicted reduction; and providing an output to the user indicative of a time requirement for increasing the state of charge of the energy storage means to a value at or above the minimum state of charge.

A selective battery control system includes a battery exchange station and an at least partially electric vehicle communicably coupled to the battery exchange station. The at least partially electric vehicle includes processing circuitry configured to determine a number of batteries needed for a trip, determine if the at least partially electric vehicle has a correct number of batteries, and in response to the at least partially electric vehicle having an incorrect number of batteries, add or remove batteries until the at least partially electric vehicle has the correct number of batteries for the trip.