Abstract: In A method of energy storage comprises receiving input energy (1) and using the input energy to compress (2) air or other process gas to produce a compressed process gas. The compressed process gas is stored (8). The compressed process gas is expanded (16) to generate output energy (17). Heat is transferred (5) from the process gas, before the process gas is stored (8) as a compressed process gas, to a hydrogen production process (10). The transferred heat is used in the hydrogen production process (10). The hydrogen may be stored (13) and subsequently used to heat to provide heat prior to, during, or after expanding (16) the compressed gas.

Abstract: A light-combining optical imager includes a spatially-curved waveguide-body complemented with at least two and preferably at least three holographic layers disposed on the surface(s) of the waveguide-body to couple light into the waveguide-body, optionally redirect its propagation inside the waveguide-body, and outcouple light from the waveguide body to form an optical image with reduced aberrations and—when desired—while expanding the pupil size of the imager upon propagation of light through the waveguide-body to achieve a one-to-one optical conjugation between an object and an image. At least one of the holographic layers includes potions having different diffraction efficiencies. At least one of the holographic layers is optionally configured to operate as a non-zero optical power lens element. Spatial separations between the holographic layers judiciously relate to dimensions of the portions of the holographic layers to achieve the desired result.

Abstract: A light-combining optical imager includes a spatially-curved waveguide-body complemented with at least two and preferably at least three holographic layers disposed on the surface(s) of the waveguide-body to couple light into the waveguide-body, optionally redirect its propagation inside the waveguide-body, and outcouple light from the waveguide body to form an optical image with reduced aberrations and—when desired—while expanding the pupil size of the imager upon propagation of light through the waveguide-body to achieve a one-to-one optical conjugation between an object and an image. At least one of the holographic layers includes potions having different diffraction efficiencies. At least one of the holographic layers is optionally configured to operate as a non-zero optical power lens element. Spatial separations between the holographic layers judiciously relate to dimensions of the portions of the holographic layers to achieve the desired result.

Abstract: A method of energy storage comprises receiving input energy (1) and using the input energy to compress (2) air or other process gas to produce a compressed process gas. The compressed process gas is stored (8). The compressed process gas is expanded (16) to generate output energy (17). Heat is transferred (5) from the process gas, before the process gas is stored (8) as a compressed process gas, to a hydrogen production process (10). The transferred heat is used in the hydrogen production process (10). The hydrogen may be stored (13) and subsequently used to heat to provide heat prior to, during, or after expanding (16) the compressed gas.

Abstract: A method of forming a ceramic matrix composite component is provided. The method includes the steps of: providing a pattern element; coating the pattern element with a ceramic slurry; drying the slurry to form a ceramic layer; forming a ceramic matrix composite body on a surface of the ceramic layer to produce a ceramic matrix composite component with the ceramic layer attached thereto.

Abstract: A vertically interleaved in-building distributed antenna system is described. The in-building distributed antenna system includes a multiple-input and multiple-output (MIMO) radio. The MIMO radio includes a first branch connector and a second branch connector. The in-building distributed antenna system further includes a first branch transport medium coupled to the first branch connector and a second branch transport medium coupled to the second branch connector. The in-building distributed antenna system further includes a plurality of antennas. The plurality of antennas includes one or more first branch antennas coupled to the first branch transport medium and one or more second branch antennas coupled to the second branch transport medium. The first branch antennas are vertically interleaved with the second branch antennas in the structure.

Abstract: A vertically interleaved in-building distributed antenna system is described. The in-building distributed antenna system includes a multiple-input and multiple-output (MIMO) radio. The MIMO radio includes a first branch connector and a second branch connector. The in-building distributed antenna system further includes a first branch transport medium coupled to the first branch connector and a second branch transport medium coupled to the second branch connector. The in-building distributed antenna system further includes a plurality of antennas. The plurality of antennas includes one or more first branch antennas coupled to the first branch transport medium and one or more second branch antennas coupled to the second branch transport medium. The first branch antennas are vertically interleaved with the second branch antennas in the structure.

Abstract: A vertically interleaved in-building distributed antenna system is described. The in-building distributed antenna system includes a multiple-input and multiple-output (MIMO) radio. The MIMO radio includes a first branch connector and a second branch connector. The in-building distributed antenna system further includes a first branch transport medium coupled to the first branch connector and a second branch transport medium coupled to the second branch connector. The in-building distributed antenna system further includes a plurality of antennas. The plurality of antennas includes one or more first branch antennas coupled to the first branch transport medium and one or more second branch antennas coupled to the second branch transport medium. The first branch antennas are vertically interleaved with the second branch antennas in the structure.