An onboard DC charger for an electric vehicle, wherein the electric vehicle includes an electric machine and a power conversion device that is a drive circuit for the electric machine and a charging circuit for the on-board battery. The one or more electric machines of the vehicle are mounted to the body for providing locomotive energy, wherein the or each machine has a stator, a rotor mounted to the stator for rotation, and one or more windings; and a controller for operating in a first state and a second state wherein, in the first state, the controller allows current to be drawn from the DC energy source for energising at least one of the one or more windings such that the electric machine provides the locomotive energy and, in the second state, the controller controls the position of the rotor relative to the stator and allows at least one of the one or more windings to be energised to provide a charging current to the DC energy source.

A system for powering an electric vehicle includes at least one electrochemical battery, a supercapacitor adder module including at least one supercapacitor battery, and a controller configured, in response to detecting that an external charging source is connected to the supercapacitor adder module, to disconnect the at least one electrochemical battery from the electric vehicle, charge the at least one supercapacitor battery from the external charging source via the supercapacitor adder module, charge the at least one electrochemical battery from the external charging source via the supercapacitor adder module, and reconnect the at least one electrochemical battery to the electric vehicle.

One aspect of the present invention pertains to a method of charging electric storage devices such as batteries. Another aspect of the present invention pertains to a system for charging electric storage devices such as batteries. Another aspect of the present invention pertains to a mobile apparatus for charging electric storage devices such as batteries.

A control system and apparatus for managing charging of electric vehicles in a transportation infrastructure and controlling at least the flight paths for drone-assisted vehicles requiring periodic charge comprises a transportation system control node connected in a first wide area network (WAN), a plurality of vehicle charging facilities distributed within the geographic region covered by the first wide area network and a charge controller connected to each of the plurality of charging facilities for brokering electric power from a power source to at least one structurally supported charge transfer apparatus maintained at each of the charging facilities.

A control system and apparatus for managing charging of electric vehicles in a transportation infrastructure and controlling at least the flight paths for drone-assisted vehicles requiring periodic charge comprises a transportation system control node connected in a first wide area network (WAN), a plurality of vehicle charging facilities distributed within the geographic region covered by the first wide area network and a charge controller connected to each of the plurality of charging facilities for brokering electric power from a power source to at least one structurally supported charge transfer apparatus maintained at each of the charging facilities.

A system for charging vehicles. The system includes a renewable energy collection device configured to collect renewable energy from one or more renewable energy sources. The system includes various components configured to store and deliver the electrical energy for dispensing. The system is further configured to receive energy from a power grid. The energy from the power grid can supplement the energy available in the system and/or supply the energy for dispensing.

A system for charging vehicles. The system includes a renewable energy collection device configured to collect renewable energy from one or more renewable energy sources. The system includes various components configured to store and deliver the electrical energy for dispensing. The system is further configured to receive energy from a power grid. The energy from the power grid can supplement the energy available in the system and/or supply the energy for dispensing.

An electric vehicle (EV) charging station for fast charging (e.g. 5 to 15 minutes) an electric vehicle (EV). The EV charging station can be configured to charge multiple EVs and multiple conventional fuel type vehicles at the same time.

There is provided a system that, when in operation, classifies one or more elements within an input signal, wherein the system: receives a compressed version of the input signal, wherein the compressed version comprises at least two sets of compressed data in a hierarchy, wherein each set of compressed data, when decoded, enables the signal to be reconstructed up to a respective level of quality; decodes the compressed version of the signal up to a first level of quality by decoding a first set of compressed data to generate a first reconstructed signal; performs a first classification operation on the first reconstructed signal; decodes the compressed version of the signal up to a second level of quality by decoding a second set of compressed data to generate a second reconstructed signal; and performs one or more second classification operations on the second reconstructed signal.

Embodiments relate to a system comprising: a first module. The first module comprises a power receiving module configured to receive an input power from an energy source. The system further comprises a second module. The second module comprises a power conversion module configured to convert the input power to an output power. The system further comprises a third module. The third module comprises a control module for configuring the first module or the second module to perform a charging operation or a discharging operation. The first module, the second module and the third module are functionally integrated in the system to perform multiple modes of the charging operation or the discharging operation. The third module controls an impedance of the input power and the output power in the second module.