Abstract: A system and method involve using a first laser to generate a laser-induced plasma filament within an optically-transparent medium, using a second laser to generate a communication signal, and using a signal combiner positioned within the path of both the first laser and the second laser to direct the communication signal through the laser-induced plasma filament to a receiver located within the optically-transparent medium.

Abstract: A system and method involve propagating, from one or more optical sources connected to a platform, more than one optical signal through a surrounding medium towards a reflective surface. Reflected optical signals, representing the propagated optical signals reflected off of the reflective surface, are then detected using a detection system coupled to the platform. An ideal optical wavelength is then selected for optical communication from the platform within the surrounding medium based upon one or more characteristics of the detected reflected optical signals.

Abstract: A system and method involve using a first laser to generate a laser-induced plasma filament within an optically-transparent medium, using a second laser to generate a communication signal, and using a signal combiner positioned within the path of both the first laser and the second laser to direct the communication signal through the laser-induced plasma filament to a receiver located within the optically-transparent medium.

Abstract: A polarimeter includes a multi-wavelength source for generating electromagnetic waves having at least two different wavelengths, means for separating electromagnetic waves, the electromagnetic waves including electromagnetic waves generated by the multi-wavelength source and electromagnetic waves received from a sample contacted by the electromagnetic waves generated by the multi-wavelength source, a fixed waveplate, wherein the fixed waveplate is configured to convert one polarization state to multiple polarization states that allow for calculations of linear and circular polarization components of the electromagnetic waves, a free space coupler, a beam splitter, and more than one detector. The polarimeter may be used in a method for high-speed measurement of linear and circular polarization components of electromagnetic waves.

Abstract: A method of fabricating an optical modulator on a silicon substrate, comprising: forming a silicon nitride layer on the silicon substrate; forming a first polycrystalline silicon layer (PSL) on the silicon nitride layer; patterning the first PSL; forming a first silicon dioxide layer (SDL) on the first patterned PSL; patterning the first SDL; forming a second PSL on the first patterned SDL; patterning the second PSL; forming a second SDL on the second patterned PSL; patterning the second SDL; forming a third PSL on the second patterned SDL; patterning the third PSL; forming a metal layer on the third patterned PSL; patterning the metal layer; removing the first and second SDLs to effect release of first and second side reflectors; forming an active layer on the metal layer; and patterning the active layer or stack to form a base reflector and associated conductive traces for biasing.

Abstract: A Electronic/Photonic Bandgap Device (NC#98614). The apparatus includes a substrate; an electronics layer operatively coupled to the substrate; and an optical bus layer operatively coupled to the electronics layer. The optical bus layer comprises at least one 3D photonic bandgap structure having at least one period operatively coupled to the electronics layer and comprising a plurality of honeycomb-like structures having a plurality of high index regions and a plurality of low index regions, wherein the plurality of honeycomb-like structures comprises at least four honeycomb-like structures layered over each other, wherein a second honeycomb-like structure is offset from a first honeycomb-like structure, wherein a third honeycomb-like structure is offset from a second honeycomb-like structure, and wherein a fourth honeycomb-like structure is not offset from the first honeycomb-like structure. The 3D photonic bandgap structure and the electronics layer are monolithically integrated over the substrate.

Abstract: An optical modulator used for optically modulating electromagnetic energy. The optical modulator comprises a substrate and three substantially planar reflectors arranged substantially mutually orthogonal to each other. The planar reflectors comprise a base reflector disposed substantially in the plane of the substrate and first and second side reflectors operably coupled to the base reflector. The optical modulator further comprises a pair of electrically conductive traces operably connected to the base reflector, an electrically conductive pad operably connected to each of the conductive traces, at least one material layer deposited on the base reflector by which its reflection properties may be altered or modulated with an applied voltage, and a biasing source operably coupled to said conductive pads for providing a modulated voltage to the base reflector.