Techniques and systems are described for power generation management. A described technique includes receiving, by a controller, a request to activate a power generator, wherein the power generator is fuel-based; receiving, by the controller, one or more sensor inputs from one or more sensors situated at or nearby the power generator; using, by the controller, the one or more sensor inputs to detect human activity around the power generator; and controlling, by the controller, an activation of the power generator in response to the request based on whether human activity is detected around the power generator.

According to the disclosure, an electronic device and a method for displaying charging information for the electronic device are provided. According to the disclosure, an electronic device comprises: a first resonator including at least one coil, a second resonator including at least one coil, at least one light emitting device including light emitting circuitry, at least one phase shifter including phase shifting circuitry, and a processor. The processor may be configured to: control the electronic device to receive a signal for changing a wirelessly chargeable area, control the at least one light emitting device to display a second wirelessly chargeable area changed from a first wirelessly chargeable area of the electronic device on a plane where the electronic device is placed in response to receiving the signal for changing the wirelessly chargeable area, and control the at least one phase shifter to supply phase-shifted power to the first resonator or the second resonator to output wireless power in a direction corresponding to the second wirelessly chargeable area.

A power supply unit for an aerosol inhaler includes: a power supply able to discharge power to a load for generating an aerosol from an aerosol generation source; a first circuit board including a resistor; and a second circuit board disposed apart from the first circuit board, and electrically connected to the first circuit board. The second circuit board includes at least one of: a control device configured to be able to control at least one of discharging and charging of the power supply; and a charging device configured to convert power which is input, into charging power for the power supply.

Power management techniques are disclosed. For instance, an apparatus may include a bidirectional voltage converter circuit, and a control module that selectively operates the bidirectional voltage converter circuit in a charging mode and a delivery mode. The charging mode converts a voltage provided by an interface (e.g., a USB interface) into a charging voltage employed by an energy storage module (e.g., a rechargeable battery). Conversely, the delivery mode converts a voltage provided by the energy storage module into a voltage employed by the interface. Other embodiments are described and claimed.

A charge management device includes an interface that acquires information related to a schedule of a user, and a control unit that manages a charge schedule of a battery of a mobile body used by the user based on the information related to the schedule of the user. The interface outputs a question about the schedule of the user and acquires an answer to the question from the user. The control unit updates the schedule of the user based on the answer from the user.

A moving object includes: a contact power receiver connected to an external contact power feeding device and configured to receive power from the external contact power feeding device; a non-contact power receiver configured to receive power from an external non-contact power feeding device in a non-contact manner; a detector configured to detect a state of an occupant boarding the moving object; and determination circuitry configured to determine which of the contact power receiver and the non-contact power receiver is utilized to receive the power based on the state of the occupant.

A system and method for providing original equipment manufacturer (OEM) control to maximize profits that include determining at least one demand based charging schedule and processing an OEM charging policy option to schedule charging of the at least one electric vehicle at a low energy production cost timeframe. The system and method also include modifying the at least one demand based charging schedule into a policy based charging schedule based on an acceptance of the OEM charging policy option by the at least one utility provider. The system and method further include facilitating payment of an incentive fee from the at least one utility provider to the OEM.

A battery with a battery management system is capable of charging the battery with recaptured energy from an energy regeneration device. The battery management system charges the battery with the energy regeneration device if the output voltage from the energy regeneration device is larger than the charging voltage of the battery.

The present invention relates to a composite charging system and method capable of producing charging power for an electric vehicle by utilizing hydrogen energy supplied to a hydrogen vehicle, and compositely connecting hydrogen energy with a power system to efficiently perform charging of the electric vehicle, and more flexibly coping with the use of energy.

The composite charging system according to the present invention comprises: a hydrogen charger which charges hydrogen into a vehicle; a hydrogen power supply system which generates and supplies power on the basis of hydrogen; a system power supply system which supplies power from a power system; an electric charger which charges the electric vehicle; and a battery power supply system which stores power supplied from the hydrogen power supply system and the system power supply system, and supplies the stored power to the electric charger.

Systems and methods are provided for coordinating and controlling power flow during bidirectional energy transfer events between an electrified vehicle and one or more charging trailers. The systems and methods may prioritize energy transfers between each connected energy based on a charge priority selection that may be manually input by a user of the system. Charge energy may be transferred to the appropriate energy unit using such a manual approach to meet customer needs with varying levels of priority according to an energy transfer prioritization control strategy that is derived from various inputs that are considered.