Abstract: A self-adjusting solar light transmission (daylighting) apparatus includes a sunlight concentrating member (e.g., a lens array) for concentrating direct sunlight in focal zone regions disposed inside a sheet containing an evenly-distributed stimuli-responsive material (SRM) that has a relatively high transparency state in the absence of concentrated sunlight, and changes to a relatively opaque (light scattering or absorbing) state in small portions located in the focal zone regions in response to concentrated direct sunlight. Thereby, 80% or more of direct sunlight is prevented from passing through the apparatus, but 80% or more of diffuse light is passed. The outer sheet surfaces are locally parallel (e.g., planar) such that sunlight scattered by the light-scattering SRM portions is transmitted by total internal reflection through the remaining transparent sheet material, and outcoupled to one or more optional solar energy absorbing structures (e.g.

Abstract: A multi-chip module (MCM) that includes alignment features is described. This MCM includes at least two substrates having facing surfaces with positive features disposed on them. Note that a given positive feature on either of the surfaces protrudes above the surface. Furthermore, the two substrates are mechanically coupled by these positive features. In particular, a given one of the positive features on one of the surfaces mates with a given subset of the positive features on the other of the surfaces. Additionally, the given subset of the positive features includes two or more of the positive features.

Abstract: A concentrating solar collector includes a solid optical structure a flat front surface, and PV cells and a micro-faceted mirror array disposed on the opposing rear surface. The micro-faceted mirrors are arranged in a sawtooth arrangement to reflect sunlight toward the front surface at angles that produces total internal reflection (TIR) and redirection of the sunlight onto the PV cells. The micro-faceted mirror array reflects sunlight onto the PV cells in an extended focus region of concentrated light that has a substantially uniform or homogeneous irradiance distribution pattern. The optical structure is a solid dielectric sheet either processed to include micro-faceted surfaces with reflective material formed thereon, or having a dielectric film including the micro-faceted mirror array adhered thereon. In one embodiment, three PV cells and four micro-faceted mirror arrays are disposed in an interleaved pattern with two side mirrors are disposed on side edges of the optical structure.

Abstract: Microfluidic pixels are utilized to produce large format displays (billboards) that are both digitally controllable and are light weight. Each microfluidic pixel includes a wall having a front (display) surface, and a microfluidic system including a reservoir disposed behind the wall, a colorant fluid, a transparent display chamber disposed in front of the wall, a conduit, and a two-way pump. In the absence of colorant fluid in display chamber, the pixel has a background appearance determined by the color (e.g., white) of the front wall surface. The pump receives a digital control signal from a digital control circuit to transfer colorant fluid from the reservoir to the display chamber by way of the conduit, whereby the pixel's appearance changes to a “colored” appearance determined by the color and amount of the colorant fluid in the display chamber.