Systems, apparatuses, and methods provide for technology that locates one or more masses of a thunderstorm system, as the thunderstorm system starts to organize and before the thunderstorm system spawns a tornado, and controls a transmission of electromagnetic radiation from the space platform to the one or more masses, wherein the transmitted electromagnetic radiation tracks the one or more masses as the thunderstorm system is starting to organize and rotate, and wherein the transmitted electromagnetic radiation prevents the thunderstorm system from rotating and spawning the tornado.

Systems, apparatuses, and methods provide for technology that locates one or more masses of a thunderstorm system, as the thunderstorm system starts to organize and before the thunderstorm system spawns a tornado, and controls a transmission of electromagnetic radiation from the space platform to the one or more masses, wherein the transmitted electromagnetic radiation tracks the one or more masses as the thunderstorm system is starting to organize and rotate, and wherein the transmitted electromagnetic radiation prevents the thunderstorm system from rotating and spawning the tornado.

An energy storage includes a first container including an inner space, a plurality of pressure vessels for compressed air that are stacked in rows inside the inner space of the first container, a tank containing a heat transfer fluid arranged inside the inner space of the first container, a compressor adapted to compress air, and a plurality of pneumatic ducts for compressed air connected to the compressor. The plurality of pneumatic ducts includes a plurality of heat exchangers adapted to enable a heat exchange between compressed air contained in the plurality of pneumatic ducts and heat transfer fluid contained inside the tank. The plurality of pneumatic ducts is connected to the plurality of pressure vessels supplying pressure vessels with compressed air, an electric turbine connected by the plurality of pneumatic ducts with the plurality of pressure vessels supplying compressed air for rotating the electric turbine to generate electric current.

In a sensor used in an energy harvesting system, electric power generated by a solar cell module is more efficiently utilized. In a sensor (100), a resistor (3) is connected in parallel with one of a first solar cell module (1a) and a second solar cell module (1b) that have mutually different current-voltage characteristics in the same illuminance environment and in series with the other one of the first solar cell module (1a) and the second solar cell module (1b). A first voltmeter (4a) measures a voltage (V1) across the first solar cell module (1a), and a second voltmeter (4b) measures a voltage (V2) across the second solar cell module (1b). A load (6) is fed with the electric power generated by the first solar cell module (1a) and the second solar cell module (1b).

A solar array assembly that includes a chassis, a top solar array assembly, a right side solar array assembly pivotable with respect to the chassis along a first horizontal axis, and a left side solar array assembly pivotable with respect to the chassis along a second horizontal axis. The right side solar array assembly includes a right central solar array assembly, a first right end solar array assembly pivotably connected to the right central solar array assembly about a first vertical axis, and a second right end solar array assembly pivotably connected to the right central solar array assembly about a second vertical axis. The left side solar array assembly includes a left central solar array assembly, a first left end solar array assembly pivotably connected to the right central solar array assembly about a third vertical axis, and a second left end solar array assembly pivotably connected to the right central solar array assembly about a fourth vertical axis.

System and method for direct solar energy to device transmission includes collecting and converting solar radiation energy to electrical energy by at least one satellite, generating a transmissive energy from the electrical energy, forming a transmissive energy beam, transmitting the energy beam from space directly to an electronic device located on Earth, receiving the energy beam by the electronic device's rectenna, converting the energy beam to alternating current, matching rectenna's antenna impedance with the rectenna's rectifying circuit impedance, rectifying the alternating current to direct current, and powering a load of the electronic device.

Embodiments disclosed herein relate to solar tracking apparatuses, systems that include the same, and methods of operating the same. An example solar tracking apparatus includes a structure attachment portion configured to be attached to a structure (e.g., a moveable or stationary structure) and to remain relatively stationary relative to the structure. The structure attachment portion may include one or more mounts configured to attach the structure attachment portion to the structure. The solar tracking apparatus also includes at least one solar panel portion coupled to the structure attachment portion. The solar panel portion may be configured to move relative to the structure attachment portion and the structure. For example, the solar tracking apparatus may include one or more actuators coupled to solar panel portion configured to move at least a portion of the solar panel portion relative to the structure attachment portion.

Embodiments disclosed herein relate to solar tracking apparatuses, systems that include the same, and methods of operating the same. An example solar tracking apparatus includes a structure attachment portion configured to be attached to a structure (e.g., a moveable or stationary structure) and to remain relatively stationary relative to the structure. The structure attachment portion may include one or more mounts configured to attach the structure attachment portion to the structure. The solar tracking apparatus also includes at least one solar panel portion coupled to the structure attachment portion. The solar panel portion may be configured to move relative to the structure attachment portion and the structure. For example, the solar tracking apparatus may include one or more actuators coupled to solar panel portion configured to move at least a portion of the solar panel portion relative to the structure attachment portion.

Systems and methods for providing solar-generated power to a display unit mounted to a vehicle are provided. One or more mounting supports connect a housing for an electronic display to the vehicle. A solar energy harvesting device is secured to an upper portion of the vehicle and is electrically connected to the electronic display.

Systems and methods for providing solar-generated power to a display unit mounted to a vehicle are provided. One or more mounting supports connect a housing for an electronic display to the vehicle. A solar energy harvesting device is secured to an upper portion of the vehicle and is electrically connected to the electronic display.