Wireless power transmission (WPT) systems are provided. For example, the WPT system can use one or more power transmitting coils and a receiver for electromagnetically coupled wireless power transfer. The electrodynamic receiver can be in the form of an electrodynamic transducer where a magnet is allowed to oscillate near a receiving coil to induce a voltage in the receiving coil, a piezoelectric transducer where the magnet causes a vibrating structure with a piezoelectric layer to move, an electrostatic transducer where movement of the magnet causes a capacitor plate to move, or a combination thereof. An alternating magnetic field from the transmitting coil(s) excites the magnet in the receiver into mechanical resonance. The vibrating magnet then functions similar to an energy harvester to induce voltage/current on an internal coil, piezoelectric material, or variable capacitor. Embodiments utilize magnetic coupling and electromechanical resonance for safe, spatially distributed, low-frequency power delivery to portable devices.

Wireless power transmission (WPT) systems are provided. For example, the WPT system can use one or more power transmitting coils and a receiver for electromagnetically coupled wireless power transfer. The electrodynamic receiver can be in the form of an electrodynamic transducer where a magnet is allowed to oscillate near a receiving coil to induce a voltage in the receiving coil, a piezoelectric transducer where the magnet causes a vibrating structure with a piezoelectric layer to move, an electrostatic transducer where movement of the magnet causes a capacitor plate to move, or a combination thereof. An alternating magnetic field from the transmitting coil(s) excites the magnet in the receiver into mechanical resonance. The vibrating magnet then functions similar to an energy harvester to induce voltage/current on an internal coil, piezoelectric material, or variable capacitor. Embodiments utilize magnetic coupling and electromechanical resonance for safe, spatially distributed, low-frequency power delivery to portable devices.

Systems and methods for wireless energy transfer are described. A transmitter unit has a transmitter resonator with a coil that is coupled to a power supply to wirelessly transmit power to a receiver unit. A receiver unit has a receiver resonator with a coil coupled to a device load. At least one of the resonators is a malleable, non-planar resonator that can be bent and shaped to conform to a patient's anatomy.

A method of configuring a metamaterial structure comprising a plurality of electrical resonators (110) that support magnetoinductive waves is disclosed. The method comprises: powering at least one of the electrical resonators (110) with an alternating current at an excitation frequency, the at least one powered electrical resonator providing a source of magnetoinductive waves in the structure; adjusting parameters of the metamaterial structure to create constructive interference of one- two- or three-dimensional magnetoinductive waves at one or more target resonators of the electrical resonators (110), to improve power transfer from the at least one powered electrical resonator to the one or more target resonators (110).

The present description relates to a wireless power transmission/reception device. The present description provides a magnetic field controlling member for focusing a magnetic field between a primary coil, which is connected to a power source of a wireless power transmission system and forms a magnetic field, and a secondary coil which is for receiving power by means of the magnetic field. The magnetic field controlling member includes: a substrate, between the primary coil and secondary coil, of which one side faces the primary coil or secondary coil; a pattern unit which is placed on the substrate and has a plurality of thin films that are positioned at a predetermined distance away from each other; and a connecting unit which electrically connects the plurality of thin films.

The present disclosure relates to a module for relaying power wirelessly to a device implanted in a user. The module may include a structure adapted to be worn by the user, a receiver configured to receive a first wireless power transmission at a first frequency, a transmitter configured to transmit a second wireless power transmission at a second frequency different from the first frequency, and a frequency changer configured to convert energy generated by the first wireless power transmission into energy for generating the second wireless power transmission. Each of the receiver, transmitter and frequency changer may be disposed on or in the structure.

A robotic agent swarm system having first robotic luminaire agents, and at least one control processor. Each agent has a suspension configured to hold the agent against an architectural surface, which includes a holonomic operational area; at least one propulsion motor configured to enable holonomic movement of the agent different locations on the architectural surface; a communication system configured to communicate with at least one other agent; a power supply operatively connected to the at least one propulsion motor and the communication system; and a light source oriented to illuminate a region around the architectural surface. The control processor is operatively associated with the agents and configured to transmit operating instructions, via at least one of the agent's respective communication system. The operating instructions include instructions for operating one or more agent's respective propulsion motor to move the agent holonomically within the holonomic operational area.

A robotic agent swarm system having first robotic luminaire agents, and at least one control processor. Each agent has a suspension configured to hold the agent against an architectural surface, which includes a holonomic operational area; at least one propulsion motor configured to enable holonomic movement of the agent different locations on the architectural surface; a communication system configured to communicate with at least one other agent; a power supply operatively connected to the at least one propulsion motor and the communication system; and a light source oriented to illuminate a region around the architectural surface. The control processor is operatively associated with the agents and configured to transmit operating instructions, via at least one of the agent's respective communication system. The operating instructions include instructions for operating one or more agent's respective propulsion motor to move the agent holonomically within the holonomic operational area.

At least some aspects of the present disclosure feature an RF interface device. The RF interface device comprises an RF receiver, a wireless reader and an output component. The RF receiver is configured to receive power wirelessly. The wireless reader is configured to interrogate a wireless device. The wireless reader is further configured to provide power to the wireless device.

At least some aspects of the present disclosure feature an RF interface device. The RF interface device comprises an RF receiver, a wireless reader and an output component. The RF receiver is configured to receive power wirelessly. The wireless reader is configured to interrogate a wireless device. The wireless reader is further configured to provide power to the wireless device.