Abstract: A novel optical fiber end structure and method for creating same in which an optical fiber end structure may comprise a cylindrical wedge having a planar surface angled with respect to the longitudinal axis of the optical fiber and a flat surface that is generally perpendicular with the longitudinal axis of the optical fiber. The device and method of the invention may employ a single or plurality of mechanically polished wedges on the end or ends of an optical fiber, which may, in a best mode, be a few mode fiber. The method and device of the invention may be used to independently modulate standing waves or linearly polarized waves, or both, allowing for a modal multiplexed system. The invention radiates independent standing wave modes and/or linearly polarized modes from the dielectric waveguide structure, and may be employed in single, few mode or multimode optical fibers.

Abstract: A novel fiber optic modal multiplexed data communication system is shown and claimed, wherein an optical fiber end structure may comprise a truncated cylindrical wedge that is angled with respect to the longitudinal axis of the optical fiber, and further comprises a lip that is generally perpendicular to the longitudinal axis of the optical fiber on both ends of the fiber. The system and method of the invention may comprise at least one but preferably a plurality of laser transmitters to illuminate an optical fiber and at least one but preferably a plurality of optical detectors to detect radiated standing wave and linear polarized modes emanating from the fiber end face. The laser transmitters may be modulated to carry information to at least one receiver, and may comprise Forward Error Correction encoding. The invention may employ single, few mode or multimode optical fibers.

Abstract: A novel optical fiber end structure and method for creating same in which an optical fiber end structure may comprise a cylindrical wedge having a planar surface angled with respect to the longitudinal axis of the optical fiber and a flat surface that is generally perpendicular with the longitudinal axis of the optical fiber. The device and method of the invention may employ a single or plurality of mechanically polished wedges on the end or ends of an optical fiber, which may, in a best mode, be a few mode fiber. The method and device of the invention may be used to independently modulate standing waves or linearly polarized waves, or both, allowing for a modal multiplexed system. The invention radiates independent standing wave modes and/or linearly polarized modes from the dielectric waveguide structure, and may be employed in single, few mode or multimode optical fibers.

Abstract: An integrated sub-millimeter and infrared reflectarray includes a reflective surface, a dielectric layer disposed on the reflective surface, and a subwavelength element array and a subwavelength element array electromagnetically coupled to the reflective surface. The subwavelength element array includes (i) electrically conductive subwavelength elements on the dielectric layer, (ii) wherein the dielectric layer comprises a plurality of dielectric subwavelength elements, or (iii) the dielectric layer includes a plurality of embedded dielectric subwavelength elements. The array includes at least one of a plurality of substantially different inter-element spacings and a plurality of substantially different dimensions for the elements.

Abstract: Hybrid microantennas and improved sensor structures incorporating hybrid microantenna embodiments are described herein. A hybrid long-wave infrared (LWIR) microantenna includes four inner pie-shaped arms in which the four inner pie-shaped arms are in a double bow-tie configuration and a plurality of outer pie-shaped arms in which a subset of the outer pie-shaped arms is connected to the four inner pie-shaped arms and the pie-shaped arms are sensitive to electric fields and absorb radiation.

Abstract: Hybrid microantennas and improved sensor structures incorporating hybrid microantenna embodiments are described herein. A hybrid long-wave infrared (LWIR) microantenna includes four inner pie-shaped arms in which the four inner pie-shaped arms are in a double bow-tie configuration and a plurality of outer pie-shaped arms in which a subset of the outer pie-shaped arms is connected to the four inner pie-shaped arms and the pie-shaped arms are sensitive to electric fields and absorb radiation.

Abstract: An integrated sub-millimeter and infrared reflectarray includes a reflective surface, a dielectric layer disposed on the reflective surface, and a subwavelength element array and a subwavelength element array electromagnetically coupled to the reflective surface. The subwavelength element array includes (i) electrically conductive subwavelength elements on the dielectric layer, (ii) wherein the dielectric layer comprises a plurality of dielectric subwavelength elements, or (iii) the dielectric layer includes a plurality of embedded dielectric subwavelength elements. The array includes at least one of a plurality of substantially different inter-element spacings and a plurality of substantially different dimensions for the elements.