A power conversion module for use with optical energy transfer and conversion system has a hemi-spherically configured housing, an array of photovoltaic chips mounted on the interior thereof, and inlet and outlet ports connected thereto. An end plate connected to the housing defines a cavity. An actively cooled high-power connector has one end connected to a fiber optic cable and the opposite end traversing the end plate and extending within the cavity. Beam forming optics within the cavity are in optical communication with the connector to disburse received optical energy in a hemispherical emission pattern of uniform flux toward an array of photovoltaic chips mounted in complementary configuration to the housing within the cavity, each chip spaced equidistantly from the beam forming optics. A heat sink within the housing has a plurality of fluid channels therethrough through which a work fluid removes heat via the outlet port. In alternative embodiments, the power conversion module includes a housing having a spherical configuration and a plurality of power conversion modules.

Embodiments of the present disclosure provide a solar cell and a solar cell module. The solar cell includes a first region and a second region, and further includes a substrate having a first surface and a second surface; a tunneling layer covering the second surface; a first emitter formed on part of the tunneling layer in the first region; and a second emitter formed on part of the tunneling layer in the second region and on the first emitter, a conductivity type of the second emitter being different from a conductivity type of the first emitter. The solar cell further includes a first electrode configured to electrically connect with the first emitter by penetrating through the second emitter; and a second electrode formed in the second region and configured to electrically connect with the second emitter.

A photovoltaic module is presented, which may include a photovoltaic panel and a converter circuit having a primary input connected to the photovoltaic panel and a secondary output galvanically isolated from the primary input. The primary input may be connectible to multiple input terminals within a junction box and at least one of the input terminals may be electrically connected to a ground. The photovoltaic module may include multiple interconnected photovoltaic cells connected electrically to multiple connectors (for example bus-bars). The photovoltaic module may include input terminals operable for connecting to the connectors and an isolated converter circuit. The isolated converter circuit may include a primary input connected to the input terminals and a secondary output galvanically isolated from the primary input.

A device includes a detector transistor, a sensing pad, a first conductive ring, a second conductive ring, a first transistor, and a second transistor. The sensing pad is over the detector transistor. The first conductive ring is over the sending pad. The second conductive ring is over the first conductive ring. The first transistor has a source/drain region electrically coupled to the first conductive ring. The second transistor has a source/drain region electrically coupled to the second conductive ring.

Described herein are photovoltaic devices and methods which utilize femtosecond (fs) lasers to create a glass/glass weld, hermetically encapsulating photovoltaic devices that provide both reduced cost and increased cell life and efficiency. For example, glass/glass welds can reduce manufacturing time and costs, increase cell life by removing encapsulant failure which is a leading cause of cell degradation and provide for increased optical properties, which improves cell efficiency.

In one example, an electronic device includes: an electronic component comprising a sensor and an electrical interconnect; a substrate comprising an electrically conductive material and a translucent mold compound, wherein the electrically conductive material is coupled to the translucent mold compound and wherein the electrical interconnect of the electronic component is coupled to the electrically conductive material of the substrate; and a translucent underfill contacting the electrical interconnect and between the translucent mold compound and the sensor. Other examples and related methods are also disclosed herein.

The present invention relates to a solar power generation assembly and method for providing same involving an array of solar generating modules on a dual-incline structure, which can achieve high energy yields over a wide range of azimuths/orientations. The assembly consists of canopy wings providing for the dual-incline structure, where, depending on specifications, the canopy wings can differ in length, width, angle of inclination, structural material and solar module or other material mounted on the surface. The canopy wings may be pivoted or hinged to enhance the energy generation and/or other functional benefits of the assembly or system, including display elements, advertising, rainwater/precipitation and snow drainage and collection and energy transmission. The assembly or system is modular and may be assembled in a long continuous configuration in which the inclination, width and tilt of the canopy wings may vary of a long distance to maintain substantially consistent energy yields as the assembly or system orientation changes.

An integrated photodetecting semiconductor optoelectronic component for measuring the intensity of each of the two colour constituents of dichromatic light irradiating the optoelectronic component includes a first SPAD and a second SPAD that detect photons over a broad range of wavelengths. The component also includes a semiconductor optical longpass filter that at least partially covers an active surface area of the first SPAD. The longpass filter is permissive to a first one of the two colour constituents of the dichromatic light and blocking the second one of the two colour constituents of the dichromatic light. The component further includes electronic circuitry for the readout and processing of detection signals delivered by the first and second SPAD. The electronic circuitry is adapted to provide a first intensity output signal and a second intensity output signal via a differential analysis based on the detection signals delivered by the first and second SPAD.

Systems, methods, and articles for a portable power case are disclosed. The portable power case is comprised of at least one battery and at least one PCB. The portable power case has at least two access ports and at least one USB port. The portable power case is operable to supply power to an amplifier, a radio, a wearable battery, a mobile phone, and a tablet. The portable power case is operable to be charged using solar panels, vehicle batteries, AC adapters, non-rechargeable batteries, and generators. The portable power case provides for modularity that allows the user to disassemble and selectively remove the batteries installed within the portable power case housing.

An image capturing and display apparatus comprises a plurality of photoelectric conversion elements for converting incident light from the outside of the image capturing and display apparatus to electrical charge signals, and a plurality of light-emitting elements for emitting light of an intensity corresponding to the electrical charge signals acquired by the plurality of photoelectric conversion elements. A pixel region is defined as a region in which the plurality of photoelectric conversion elements are arranged in an array. Signal paths for transmitting signals from the plurality of photoelectric conversion elements to the plurality of light-emitting elements lie within the pixel region.