A finger-worn wearable ring device may include a ring-shaped housing, a printed circuit board, and a sensor module that includes one or more light-emitting components and one or more light-receiving components. The wearable ring device may further include a communication module configured to wirelessly communicate with an application executable on a user device.

Systems for generating solar power are provided. One such system includes a solar radiation collector and one or more side-emitting fiber-optic cables, coupled to the solar radiation collector. The system further includes one or more photovoltaic cell enclosures, including an outer housing and one or more photovoltaic cells, wherein the one or more side-emitting fiber-optic cables is positioned within the outer housing and configured to emit, to the one or more photovoltaic cells, solar radiation collected from the solar radiation collector.

A Concentrating PhotoVoltaic (CPV) system employs an inflatable non-imaging CPC concentrator to concentrate sunlight to realize extremely low cost and a synergistically combined photonic crystal waveguide solar spectrum splitter and perovskite integrated circuitry solar cell package to realize ultra-high conversion efficiency of solar radiation. The corporation of band gap variable perovskite materials into the integrated circuit solar cell not only reduces the cost and raises the efficiency of the photovoltaic package as the receiver, but also addresses the unstable issue of the perovskite materials through sealing the perovskite materials into package to prevent moisture, reducing the heat generation to low the temperature, and filtering the UV light and channel to other elemental solar made of broader band gap photovoltaic materials.

Aspects of the disclosure are directed to generating solar power. In accordance with one aspect, a method for solar power generation, the method including: filtering a light to generate a filtered light and a rejected light; concentrating the filtered light; and passively radiating the rejected light.

A hydrogen production apparatus including a photocatalyst and generating hydrogen from water includes a wavelength separation unit separating sunlight by wavelength, an infrared light conversion unit converting infrared light separated by the wavelength separation unit to visible light, and an ultraviolet light conversion unit converting ultraviolet light separated by the wavelength separation unit to visible light.

A light-modulating device includes optical microstructures, each including a topmost layer, a bottommost layer, and in-between layers. The topmost layer extends in a first predetermined axis. The bottommost layer extends in a last predetermined axis which turns about a center axis such that an incident light beam passing through the topmost layer in an incident route is modulated to permit the light beam emitting from the bottommost layer to impinge upon a solar concentrator disposed below the light-modulating device along an impinging route different from the incident route. The in-between layers are sequentially turned about the center axis by an incremental degree toward the last predetermined axis.

A structure and method for utilizing natural light indoors or in the interior in a moving space are disclosed. The structure includes: at least one natural light condenser configured to reflect the natural light; a natural light transmitter configured such that the natural light reflected by the at least one natural light condenser is moved to the natural light transmitter; a smart lamp unit including an artificial light generator; a smart lamp driver located adjacent to the smart lamp unit and configured to move the smart lamp unit; and a controller connected to the at least one natural light condenser, the natural light transmitter, the smart lamp unit, and the smart lamp driver so as to transmit and receive information therewith. The controller is configured to combine artificial light with the natural light in response to a user request signal to radiate a combination of the artificial and natural light.

A smart ring includes a curved housing having a U-shape interior storing components including: a curved battery approximately conforming to the curved housing, a semi-flexible PCB approximately conforming to the curved housing and having mounted thereon: a motion sensor for generating motion data from physical perturbations of the smart ring, a memory for storing executable instructions, a transceiver for sending data to a client computer, a temperature sensor, and a processor for receiving motion data and performing executable instructions in response thereto, and a potting material disposed in the interior, forming an interior wall of the smart ring, wherein the potting material encapsulates the components and is substantially transparent to visible light, infrared light, and/or ultraviolet light.

A non-imaging optical concentrator, including a top portion, a body, and a bottom portion, wherein the top portion is configured to receive an incident light and transmit the received incident light to the body when the incident light is within an angle of acceptance for the non-imaging optical concentrator, and where the body is configured to reflect the incident light transmitted by the top portion to the bottom portion when the incident light is within the angle of acceptance for the non-imaging optical concentrator, and wherein the top portion is configured to split or diverge the incident light into two or more directions when the incident light is within the angle of acceptance for the non-imaging optical concentrator.

An optical collection apparatus includes a plurality of light transmissive optical reflectors and a plurality of planar bifacial solar cells. Each light transmissive optical reflector is configured to transmit indirect light impinging on first and second collection sides thereof. First and second photovoltaic sides of each of the plurality of bifacial solar cells are positioned to collect indirect light impinging thereon. The planar bifacial solar cells are arranged such that at least one light transmissive optical reflector of the plurality of light transmissive optical reflectors is positioned between consecutive ones of the planar bifacial solar cells. Each light transmissive optical reflector of the plurality of light transmissive optical reflectors is configured to reflect direct incoming light impinging on the first collection side thereof towards the first photovoltaic side of a corresponding one of the planar bifacial solar cells. A solar collection and shading system is also contemplated.