The invention comprises a free and renewable energy source and method for generating a superimposed magnetic field, for establishing a resonant magnetic field interface with the electromagnetic field generated by an external dipole energy source, whereby, the energy extracted from the superimposed magnetic field is converted to usable energy and distributed to the desired load. Whereby, said generated superimposed magnetic field is precisely tuned to a desired resonance frequency by variable resistance and capacitance comprised of controlled inorganic chemical reactions and magnetics. The invention creates an autonomous, secure, efficient, and effective power system designed to generate megawatts of power through extracting energy from carrier waves synchronized to the proton precision frequencies and distribute the generated power through existing power distribution stations or autonomous microgrids. Thereby, eliminating dependance on the conventional centralized power grid while providing safeguards ensuring current and future power requirements are satisfied.

The invention comprises a free and renewable energy source and method for generating a superimposed magnetic field, for establishing a resonant magnetic field interface with the electromagnetic field generated by an external dipole energy source, whereby, the energy extracted from the superimposed magnetic field is converted to usable energy and distributed to the desired load. Whereby, said generated superimposed magnetic field is precisely tuned to a desired resonance frequency by variable resistance and capacitance comprised of controlled inorganic chemical reactions and magnetics. The invention creates an autonomous, secure, efficient, and effective power system designed to generate megawatts of power through extracting energy from carrier waves synchronized to the proton precision frequencies and distribute the generated power through existing power distribution stations or autonomous microgrids. Thereby, eliminating dependance on the conventional centralized power grid while providing safeguards ensuring current and future power requirements are satisfied.

A mechanical device that can generate decentralized electrical power and/or hydraulic fluid pressure on a continual basis, using fully integrated omnipresent energy sources which remain unchanged.

A mechanical device that can generate decentralized electrical power and/or hydraulic fluid pressure on a continual basis, using fully integrated omnipresent energy sources which remain unchanged.

A power stealing system having an electrical load, a capacitive element having an input connected to the electrical load. Some power from the electrical load may go through the capacitive element to an input of a rectifier. A voltage regulator may have an input connected to an output of the rectifier to set and control a voltage level of the electrical power from the rectifier, and provide an output of power stolen from the electrical load. An amount of power flowing through the capacitive element may be less than one percent of power flowing through the electrical load.

A power stealing system having an electrical load, a capacitive element having an input connected to the electrical load. Some power from the electrical load may go through the capacitive element to an input of a rectifier. A voltage regulator may have an input connected to an output of the rectifier to set and control a voltage level of the electrical power from the rectifier, and provide an output of power stolen from the electrical load. An amount of power flowing through the capacitive element may be less than one percent of power flowing through the electrical load.

A system for controlling an interaction of a surface with an impinging electromagnetic wave is provided. The system comprises a surface comprising a plurality of controllable elements, wherein each of the controllable elements is configured to adjust its electromagnetic behavior based on a control signal received by the controllable element, a sensing unit configured to detect a state of an environment of the surface and/or one or more wave attributes of an electromagnetic wave impinging on the surface, a control unit configured to determine, based on the detected state of the environment and/or the one or more wave attributes, a control state of the controllable elements, in which the electromagnetic behavior of the controllable elements is adjusted such that the surface interacts with the impinging electromagnetic wave in a predefined manner, and an adjusting unit configured to determine.

A system for controlling an interaction of a surface with an impinging electromagnetic wave is provided. The system comprises a surface comprising a plurality of controllable elements, wherein each of the controllable elements is configured to adjust its electromagnetic behavior based on a control signal received by the controllable element, a sensing unit configured to detect a state of an environment of the surface and/or one or more wave attributes of an electromagnetic wave impinging on the surface, a control unit configured to determine, based on the detected state of the environment and/or the one or more wave attributes, a control state of the controllable elements, in which the electromagnetic behavior of the controllable elements is adjusted such that the surface interacts with the impinging electromagnetic wave in a predefined manner, and an adjusting unit configured to determine.

A multi-sensor data fusion-based self-powered online monitoring system for a transmission line includes a plurality of detection nodes, an optical communication receiving and demodulation module, and a data processing module. The detection nodes each include a vibration energy harvesting module, a sensing module, and an optical communication modulation and transmitting module. The detection node uses a triboelectric nanogenerator (TENG) to convert and harvest energy, uses the sensing module to acquire a plurality of types of sensing data, and uses the optical communication modulation and transmitting module to modulate and transmit the sensing data. The optical communication receiving and demodulation module correspondingly receives and demodulates the sensing data, and transmits the sensing data to the data processing module for processing. The processing includes using a weighted least square method to fuse homogeneous sensing data and using a fuzzy comprehensive evaluation method to analyze heterogeneous sensing data.

A multi-sensor data fusion-based self-powered online monitoring system for a transmission line includes a plurality of detection nodes, an optical communication receiving and demodulation module, and a data processing module. The detection nodes each include a vibration energy harvesting module, a sensing module, and an optical communication modulation and transmitting module. The detection node uses a triboelectric nanogenerator (TENG) to convert and harvest energy, uses the sensing module to acquire a plurality of types of sensing data, and uses the optical communication modulation and transmitting module to modulate and transmit the sensing data. The optical communication receiving and demodulation module correspondingly receives and demodulates the sensing data, and transmits the sensing data to the data processing module for processing. The processing includes using a weighted least square method to fuse homogeneous sensing data and using a fuzzy comprehensive evaluation method to analyze heterogeneous sensing data.