Abstract: A system for aligning components of an imaging device includes an imaging device, and a test camera. The imaging device includes a lens and a focal plane array (FPA). The FPA defines an optical axis and includes at least two test elements configured and adapted to emit a light through the lens. The test camera is configured and adapted to be mounted to and pre-aligned with the lens of the imaging device to receive a light from the at least two test elements.

Abstract: In accordance with at least one aspect of this disclosure, a photodiode structure can include a charge layer comprised of undoped InP, and a detector active area forming a junction with the charge layer and having edges configured to prevent edge breakdown. The location of the junction can be controlled through a diffusion of the detector active area or through an epitaxially grown doped region, for example. The photodiode structure can also include a charge control layer comprised of doped InP. The charge control layer can include a thickness and carrier concentration configured to achieve a predetermined gain, high speed, low dark current, and low break down voltage.

Abstract: A system and method providing for the detection of an input signal, either optical or electrical, by using a single independent discrete amplifier or by distributing the input signal into independent signal components that are independently amplified. The input signal can either be the result of photoabsorption process in the wavelengths greater than 950 nm or a low-level electrical signal. The discrete amplifier is an avalanche amplifier operable in a non-gated mode while biased in or above the breakdown region, and includes a composite dielectric feedback layer monolithically integrated with input signal detection and amplification semiconductor layers.

Abstract: A system and method providing for the detection of an input signal, either optical or electrical, by using a single independent discrete amplifier or by distributing the input signal into independent signal components that are independently amplified. The input signal can either be the result of photoabsorption process in the wavelengths greater than 950 nm or a low-level electrical signal. The discrete amplifier is an avalanche amplifier operable in a non-gated mode while biased in or above the breakdown region, and includes a composite dielectric feedback layer monolithically integrated with input signal detection and amplification semiconductor layers.

Abstract: A diamond based Blue/UV light emitting source is disclosed. The source includes a diamond substrate having a first conductivity type, a first aluminum gallium nitride layer above the diamond substrate having the same conductivity type as the substrate, a bulk or a quantum well structure on the AlGaN layer formed of a plurality of repeating sets of alternating layers selected from among GaN, InGaN, and AlInGaN, a second AlGaN layer on the quantum well or the bulk active layer having the opposite conductivity type as the first AlGaN layer, a contact structure on the second AlGaN layer having the opposite conductivity type from the substrate and the first AlGaN layer, an ohmic contact to the diamond substrate, and an ohmic contact to the contact structure.

Abstract: A diamond based Blue/UV light emitting source is disclosed. The source includes a diamond substrate having a first conductivity type, a first aluminum gallium nitride layer above the diamond substrate having the same conductivity type as the substrate, a bulk or a quantum well structure on the AlGaN layer formed of a plurality of repeating sets of alternating layers selected from among GaN, InGaN, and AlInGaN, a second AlGaN layer on the quantum well or the bulk active layer having the opposite conductivity type as the first AlGaN layer, a contact structure on the second AlGaN layer having the opposite conductivity type from the substrate and the first AlGaN layer, an ohmic contact to the diamond substrate, and an ohmic contact to the contact structure.

Abstract: An improved coating for optical fibers is described. The present invention is a dimensionally precise and uniform coating with low-porosity. The improved coating is applied via sputtering within a vacuum chamber. Environmental conditions are monitored within a cylindrical magnetron during sputtering. Sputtering is adjusted or temporarily ceased when environmental conditions approach a damage threshold. Sputtered particles within a plasma cloud are dimensionally similar and adhere to an optical fiber in a volume efficient arrangement forming a more precise, denser, and more adherent coating. Embodiments of the present invention provide improved pull strength by compressively constraining the optical fiber within the coating and by closing microcracks.

Abstract: An improved coating for optical fibers is described. The present invention is a dimensionally precise and uniform coating with low-porosity. The improved coating is applied via sputtering within a vacuum chamber. Environmental conditions are monitored within a cylindrical magnetron during sputtering. Sputtering is adjusted or temporarily ceased when environmental conditions approach a damage threshold. Sputtered particles within a plasma cloud are dimensionally similar and adhere to an optical fiber in a volume efficient arrangement forming a more precise, denser, and more adherent coating. Embodiments of the present invention provide improved pull strength by compressively constraining the optical fiber within the coating and by closing microcracks.

Abstract: An improved coating for optical fibers and a method for applying the improved coating are described. The present invention is a dimensionally precise and uniform coating with low-porosity. The improved coating is applied via sputtering within a vacuum chamber. Environmental conditions are monitored within a cylindrical magnetron during sputtering. Sputtering is adjusted or temporarily ceased when environmental conditions approach a damage threshold. Sputtered particles within a plasma cloud are dimensionally similar and adhere to an optical fiber in a volume efficient arrangement forming a more precise, denser, and more adherent coating. Embodiments of the present invention provide improved pull strength by compressively constraining the optical fiber within the coating and by closing microcracks.

Abstract: An improved coating for optical fibers and a method for applying the improved coating are described. The present invention is a dimensionally precise and uniform coating with low-porosity. The improved coating is applied via sputtering within a vacuum chamber. Environmental conditions are monitored within a cylindrical magnetron during sputtering. Sputtering is adjusted or temporarily ceased when environmental conditions approach a damage threshold. Sputtered particles within a plasma cloud are dimensionally similar and adhere to an optical fiber in a volume efficient arrangement forming a more precise, denser, and more adherent coating. Embodiments of the present invention provide improved pull strength by compressively constraining the optical fiber within the coating and by closing microcracks.