Abstract: A signal transmission line or an electrical connector includes an inner electrical conductor, an outer electrical conductor, a dielectric region between the inner electrical conductor and the outer electrical conductor, and an electrically thin resistive layer within the dielectric region and concentric with the inner electrical conductor and the outer electrical conductor. The electrically thin resistive layer is a resistive layer configured to be transparent to a substantially transverse-electromagnetic (TEM) mode of transmission, while absorbing higher order modes of transmission.

Abstract: A coaxial transmission line, e.g. a coaxial cable, includes an inner electrical conductor, an outer electrical conductor, a dielectric region between the inner electrical conductor and the outer electrical conductor, and an electrically thin resistive layer within the dielectric region and concentric with the inner electrical conductor and the outer electrical conductor. The electrically thin resistive layer is a resistive layer configured to be transparent to a subtantially transverse-electromagnetic (TEM) mode of transmission, while absorbing higher order modes of transmission.

Abstract: A probe includes a main electro-optical modulator (130), first (150) and second (160) optical couplers each having a respective input (152, 162), through (154, 164) and isolated (156, 166) port, and reference (170) and test (174) optical detectors. Reference light and test light, respectively, are received at the inputs (152, 162) of the optical couplers (150, 160). Main electro-optical modulator 130 includes an RF through-line (136) between input (132) and output (134) RF connectors, and a modulator optical path (138) alongside the RF through-line. The first and second optical couplers couple the reference and test light to opposite ends of the modulator optical path. The reference and test optical detectors are coupled to the second and first isolated ports (166, 156), respectively, to generate reference and test IF signals respectively representing forward and reverse RF signal propagation along the RF through-line.

Abstract: A system is provided for monitoring communication in a wireless network. The system comprises a sniffer device comprising a first antenna, and a beamsplitter having a curved shape and configured to reflect a portion of a beam transmitted by a second antenna toward the first antenna while transmitting a remaining portion of the beam toward a target.

Abstract: A compact, ultra-broadband antenna with doughnut-like radiation pattern is provided as including a first assembly having first and second ends; a second assembly having first and second ends, the first and second ends each configured to have a substantially hemispherical shape; and a cable configured to extend through the first and second assemblies and out each of the first and second ends.

Abstract: A plasma generation device includes: a substrate having a first surface and a second surface; a stripline resonant ring disposed on the first surface of the substrate, and defining a discharge gap; a pair of electrode extensions connected to the stripline resonant ring at the discharge gap; a ground plane disposed on the second surface of the substrate; a gas flow element configured to flow gas between at least one of: (1) the discharge gap, and (2) the pair of electrode extensions; and a structure disposed adjacent the substrate to form an enclosure that substantially encloses at least a region including the discharge gap and the electrode extensions, the enclosure being adapted to contain a plasma.

Abstract: A microwave imaging system uses microwave radiation provided by a microwave source to image targets. The system includes an array of antenna elements that are capable of being programmed with a respective direction coefficient to direct the microwave illumination from the microwave source toward a position on the target. The antenna elements are further capable of being programmed to receive reflected microwave illumination reflected from the position on the target. A processor is operable to measure an intensity of the reflected microwave illumination to determine a value of a pixel within an image of the target. Multiple beams can be directed towards the target to obtain corresponding pixel values for use by the processor in constructing the image.

Abstract: A system is provided for monitoring communication in a wireless network. The system comprises a sniffer device comprising a first antenna, and a beamsplitter having a curved shape and configured to reflect a portion of a beam transmitted by a second antenna toward the first antenna while transmitting a remaining portion of the beam toward a target.

Abstract: An antenna array for use within a microwave imaging system to capture a microwave image of a target is selectively programmed to optimize one or more parameters of the microwave imaging system. The array includes a plurality of antenna elements, each capable of being programmable with a respective phase shift to direct a beam of microwave radiation toward the target such that the microwave radiation from each of the plurality of antenna elements arrives at the target substantially in-phase. To optimize a parameter of the microwave imaging system, the phase shifts of selective ones of the antenna elements are altered, while still maintaining the substantially in-phase microwave radiation at the target.

Abstract: A plasma generation device includes: a substrate having a first surface and a second surface; a stripline resonant ring disposed on the first surface of the substrate, and defining a discharge gap; a pair of electrode extensions connected to the stripline resonant ring at the discharge gap; a ground plane disposed on the second surface of the substrate; a gas flow element configured to flow gas between at least one of: (1) the discharge gap, and (2) the pair of electrode extensions; and a structure disposed adjacent the substrate to form an enclosure that substantially encloses at least a region including the discharge gap and the electrode extensions, the enclosure being adapted to contain a plasma.

Abstract: An illumination device provides light to a flowing gaseous sample. The device includes a structure including a cavity configured to have a microplasma disposed therein. The cavity substantially encircles a cross-section of a channel that is configured to pass the flowing gaseous sample therethrough. The cavity is defined in part by an interior wall of the structure separating the cavity from the channel. The interior wall includes at least one orifice passing therethrough configured to provide to the flowing gaseous sample light generated by the microplasma. At least one electrode is configured to supply energy to the microplasma within the cavity.

Abstract: A broadband binary phased antenna includes an array of symmetric antenna elements, each being connected to a respective symmetric switch. The symmetric antenna elements are each symmetrical about a mirror axis of the antenna element and include feed points on either side of the mirror axis capable of creating opposite symmetric field distributions across the symmetric antenna element. The opposite symmetric field distributions are binary phase-shifted with respect to one another. The symmetric switch is connected to the feed points to selectively switch between the opposite symmetric field distributions.

Abstract: A plurality of antenna clusters form an antenna array used in microwave imaging. Each antenna cluster has at least two antenna elements and an active device. The active device controls the two antenna elements to direct microwave radiation to and from an object to capture a microwave image of the object.

Abstract: An approach is described for identifying sites of imminent skin breakdown in amputee prosthesis users. Thermal recovery time (TRT) for a limb is optically determined using an infrared camera. TRT is the time interval for the temperature of the skin to achieve 70% of its maximum value during a 10-minute recovery period after a subject has completed a standing/walk-in-place procedure. A limb tolerance map is produced in which 5×5 pixel squares are colored to indicate their TRT and labeled to indicate a temperature vs. time curve (indicative of blood flow characteristics) for the square. TRT data can also be used for prosthetic fitting and socket replacement, by locating tolerant/intolerant regions on a limb and providing a visual “limb tolerance map” for a proposed socket design and applied to other areas, such as the design of shoes for patients with insensate feet, cushions for wheelchair users, and mattresses for bedridden patients.

Abstract: A method of stimulating homologous recombination by creating at least one nick in a targeted polynucleotide sequence. Wherein nonhomologous recombination is suppressed resulting in increasing the ratio of targeted to nontargeted events. A method of increasing double strand break-initiated gene targeting by inducing a nick in a targeted polynucleotide sequence, wherein overall recombination levels are increased. A method of increasing homologous recombination employing a recombinase that releases the ends in living cells by stimulating homolgous recombination to higher levels than those attainable with standard nucleases. A composition for stimulating homologous recombination including a nicking mechanism for creating nicks in a polynucleotide, wherein the nicking mechanism stimulates homologous recombination. A composition for stimulating homologous recombination including a nicking endonucleases. Various kits for stimulating homologous recombination.

Abstract: Grating lobe free scanning in a phased array with sparse element spacing is obtained by restricting the maximum scan angle for elements in the array, and arranging the elements in a convex form. One convex form is a paraboloid, which may be continuous, or piecewise in nature, tiled with flat segments.

Abstract: Grating lobe free scanning in a phased array with sparse element spacing is obtained by restricting the maximum scan angle for elements in the array, and cladding the array. Array elements may be integrated into the cladding.

Abstract: A coaxial bi-modal imaging system is produced by aligning a microwave transceiver, an optical camera and an antenna array in a coaxial configuration. The microwave transceiver is operable to emit microwave radiation to illuminate an object and to receive reflected microwave radiation reflected from the object to capture a microwave image of the object. The antenna array includes a plurality of antenna elements, each programmable with a respective transmit direction coefficient to direct the microwave radiation emitted from said microwave transceiver toward a target on the object, and each programmable with a respective receive direction coefficient to direct the reflected microwave radiation reflected from said target towards said microwave transceiver. The optical camera is configured to capture an optical image of said object.

Abstract: A coaxial bi-modal imaging system is produced by aligning a microwave transceiver, an optical camera and an antenna array in a coaxial configuration. The microwave transceiver is operable to emit microwave radiation to illuminate an object and to receive reflected microwave radiation reflected from the object to capture a microwave image of the object. The antenna array includes a plurality of antenna elements, each programmable with a respective transmit direction coefficient to direct the microwave radiation emitted from said microwave transceiver toward a target on the object, and each programmable with a respective receive direction coefficient to direct the reflected microwave radiation reflected from said target towards said microwave transceiver. The optical camera is configured to capture an optical image of said object.

Abstract: A plurality of antenna clusters form an antenna array used in microwave imaging. Each antenna cluster has at least two antenna elements and an active device. The active device controls the two antenna elements to direct microwave radiation to and from an object to capture a microwave image of the object.