Abstract: Methods and apparatus for a near-field signal system to generate signals underwater for navigation and/or communication. In one embodiment, a system includes a signal processing module coupled to a first antenna to transmit near-field signals underwater and a second antenna to receive near-field signals underwater transmitted by the first antenna. In one embodiment, a wetsuit includes an integrated near-field signal system.

Abstract: A path is automatically routed for a sensor platform that projects a constant sensor footprint to the surface to observe a region of interest without crossing into an excluded area and to tracking that path. The path is routed by defining a bounding region around the region of interest and defining a convex hull around an obstacle within the region of interest. A parallel arrangement of rectangular planks is generated from each edge of the convex hull out to the bounding region. The extent of each rectangular plank is bounded at one end by the intersection of the plank with the bounding region and at the other end by the intersection of the plank with an extension of a next edge of the convex hull. The path is routed to traverse the parallel arrangement of rectangular planks for each edge of the convex hull in a raster scan pattern and to circle the convex hull in a clockwise or counter-clockwise direction.

Abstract: Methods and apparatus for a near-field signal system to generate signals underwater for navigation and/or communication. In one embodiment, a system includes a signal processing module coupled to a first antenna to transmit near-field signals underwater and a second antenna to receive near-field signals underwater transmitted by the first antenna. In one embodiment, a wetsuit includes an integrated near-field signal system.

Abstract: A quantum computing device and method employs qubit arrays of entangled states using negative refractive index lenses. A qubit includes a pair of neutral atoms separated by or disposed on opposite sides of a negative refractive index lens. The neutral atoms and negative refractive index lens are selectively energized and/or activated to cause entanglement of states of the atoms. The quantum computing device enjoys a novel architecture that is workable and scalable in terms of size and wavelength.

Abstract: A quantum computing device and method employs qubit arrays of entangled states using negative refractive index lenses. A qubit includes a pair of neutral atoms separated by or disposed on opposite sides of a negative refractive index lens. The neutral atoms and negative refractive index lens are selectively energized and/or activated to cause entanglement of states of the atoms. The quantum computing device enjoys a novel architecture that is workable and scalable in terms of size and wavelength.

Abstract: A band gap discontinuity is propagated across a Photonic Crystal (PC) to capture thermal energy in a region near the primary emission wavelength of the Planck spectral distribution and transfer that energy to a different spectral region where it is emitted. To extend the range of frequency shifting beyond the width of a single band gap, the intrinsic control parameters (e.g., lattice geometry factors, scattering element geometric factors, and variations in the index of refraction) are spatially varied across the PC to form a band gap gradient. Propagation of the band gap discontinuity, starting in the infrared wavelength region where the thermally generated electromagnetic energy is concentrated and propagating towards the long wavelength region, locally captures the thermal electromagnetic radiation, shifts it downwards in frequency, and pushes the lower-frequency thermal electromagnetic radiation on to the next region. The same principles apply to shift the frequency to shorter wavelengths.

Abstract: Although THz radiation is naturally emitted by hot objects, the intensity levels are too weak to be considered as a practical THz source for most applications. Photonic crystal structures are used to modify the thermal emission peak associated with the standard Planck blackbody spectral distribution so that the THz region is dramatically enhanced. The photonic crystal core is preferably combined with variable Q defect cavities and a wave guiding and power combining structure so that the radiated THz energy is efficiently collected and directed to an output antenna. Higher THz emissions are realized by embedding a finer (higher frequency) photonic crystal structure within a coarser (lower frequency) structure.