Abstract: An articulating shaft for a steerable catheter system includes a tubular body having a longitudinal central axis and at least one main lumen with a distal end and a proximal end. The shaft further includes at least one wire support element forming at least one wire lumen for supporting at least one actuating wire, the main lumen and the wire lumen are integrally formed in an extrusion part having a uniform hardness in an axial and a radial direction. A plurality of removed sections or cuts of the shaft extend in a radial direction and are distanced from each other in an axial direction.

Abstract: A conduit for creating a passage from a right atrium to a left atrium, through a mitral valve into the left ventricle, and to provide a passage from the left ventricle into the aortic valve. The conduit includes an elongate tubular member having a shaft with a proximal section and a distal loop section at a distal end of the proximal section. The distal loop section includes a proximal curve, a distal curve, a generally straight segment extending between the curves, and a distal tip. The shaft in the distal loop section curves back on itself so that proximal curve is formed by a part of the shaft that is closer along the length of the shaft to the distal tip.

Abstract: A conduit for creating a passage from a right atrium to a left atrium, through a mitral valve into the left ventricle, and to provide a passage from the left ventricle into the aortic valve. The conduit includes an elongate tubular member having a shaft with a proximal section and a distal loop section at a distal end of the proximal section. The distal loop section includes a proximal curve, a distal curve, a generally straight segment extending between the curves, and a distal tip. The shaft in the distal loop section curves back on itself so that proximal curve is formed by a part of the shaft that is closer along the length of the shaft to the distal tip.

Abstract: A conduit for creating a passage from a right atrium to a left atrium, through a mitral valve into the left ventricle, and to provide a passage from the left ventricle into the aortic valve. The conduit includes an elongate tubular member having a shaft with a proximal section and a distal loop section at a distal end of the proximal section. The distal loop section includes a proximal curve, a distal curve, a generally straight segment extending between the curves, and a distal tip. The shaft in the distal loop section curves back on itself so that proximal curve is formed by a part of the shaft that is closer along the length of the shaft to the distal tip.

Abstract: A tunable laser device (1) comprises integrally formed first and second ridge waveguides (5, 6). A longitudinally extending ridge (12) defines first and second light guiding regions (19, 20) of the first and second waveguides (5, 6) A plurality of first and second slots (27, 28) extending laterally in the ridge (12) adjacent the first and second waveguides (5, 6), produce first and second mirror loss spectra of the respective first and second waveguides (5, 6) with minimum peak values at respective first and second wavelength values. The spacing between the second slots (28) is different to that between the first slots (27) so that with one exception the minimum peak values of the first and second mirror loss spectrum occur at different wavelength values. The first and second waveguides (5, 6) are independently pumped with variable currents to selectively vary the common wavelength at which the minimum peak values of the first and second mirror loss spectra occur to produce Vernier tuning of the device.

Abstract: The present application provides a semiconductor Fabry-Perot dual mode lasing device having terahertz characteristics resulting in significant advantages over the prior art including for example operation at room temperatures and the absence of re-growth processing requirements.

Abstract: Method for coherently combining signals received from two widely separated antenna apertures (204, 206). The method includes positioning a first antenna aperture (204) at a first location spaced apart a distance with respect to a second location of a second antenna aperture (206). A distance between the first antenna aperture and the second antenna aperture is selected to be at least a plurality of wavelengths at a predetermined operating frequency of the first antenna aperture and the second antenna aperture. An antenna beam or pattern (208, 210) from each antenna aperture (204, 206) is directed toward a target (212) positioned at a location remote from the first antenna aperture and the second antenna aperture. Adaptive digital processing (416) is then used to coherently combine the signals independently received by each aperture from the common source.

Abstract: A tunable laser device (1) comprises integrally formed first and second ridge waveguides (5, 6). A longitudinally extending ridge (12) defines first and second light guiding regions (19, 20) of the first and second waveguides (5, 6) which communicate with each other. A plurality of first slots (27) extending laterally in the ridge (12) adjacent the first waveguide (5), and a plurality of second slots (28) extending laterally in the ridge (12) adjacent the second waveguide (6) produce first and second mirror loss spectra of the respective first and second waveguides (5, 6) with minimum peak values at respective first and second wavelength values.

Abstract: An antenna system may include a base having an opening therein, and a plurality of swing arms each having a concave elongate shape and opposing ends pivotally connected to the base to permit a swinging motion within the opening of the base. The swing arms may be transverse to one another thereby defining an overlap area between the swing arms. The antenna system may further include a respective swing arm positioner connected between the base and each swing arm. An antenna carriage may be movable along the swing arms and which remains at the overlap area between the swing arms. A positioning controller may be connected to each swing arm positioner, and an antenna may be connected to the antenna carriage.

Abstract: An animal tote includes a container having a bottom wall and opposed side and end walls connected together to form an interior cavity having an open top covered by a lid. A plurality of spaced openings constituting air holes is formed in the walls and a divider system is positioned in the cavity to form a plurality of separate inner compartments, with each compartment being closed by a separate cover. The container lid is positioned over the individual covers when the compartment is closed.

Abstract: An animal tote includes a container of thermoplastic material having a bottom wall and opposed side and end walls connected together to form an interior cavity having an open top covered by a lid. A plurality of arrays of spaced openings constituting air holes is formed in the walls and top. A layer of filter material and a protective layer of screen or mesh material, both constructed of a thermoplastic material, are positioned over the air holes and both layers are attached to the container by sonic welding. A divider system may be positioned in the cavity to form a plurality of separate inner compartments, with each compartment being closed by a separate cover. The container lid is positioned over the individual covers when the container is closed.

Abstract: An antenna system may include a base having an opening therein, and a swing arm having a concave elongate shape and opposing ends pivotally connected to the base to permit a swinging motion of the swing arm within the opening in the base. A swing arm positioner may be connected between the swing arm and the base. The antenna system may also include an antenna carriage movable along the swing arm. An antenna carriage positioner may be connected between the antenna carriage and the swing arm. A positioning controller may be connected to the swing arm positioner and the antenna carriage positioner, and an antenna may be connected to the antenna carriage.

Abstract: A phased array antenna may include a plurality of antenna elements, at least one respective phase shifter connected to each antenna element, and at least one respective gain element connected to each antenna element. The phased array antenna may further include at least one controller for determining and controlling both phases and gains of the phase shifters and gain elements, respectively, to provide beamsteering in a first direction for a signal of interest. The controller may also iteratively determine and control phases of the phase shifters to provide a null in a second direction for a signal not of interest, and without determining or controlling gains of the gain elements.

Abstract: A phased array antenna may include a substrate and an array of antenna elements carried thereby, and the antenna elements may be arranged along an imaginary spiral. The antenna may further include at least one control element connected to each antenna element, and at least one controller serially communicating with the control elements so that updated control data for beam steering is sequentially implemented by the control elements to thereby cause a gradual change in beam steering.

Abstract: A antenna array (20) includes a plurality of periodic or aperiodic arranged sub-arrays (22). Each sub-array (22) includes a plurality of antenna elements (32) arranged in the form of a spiral (30). The sub-arrays (22) can comprise various spiral shapes to provide the required physical configuration and operational parameters to the antenna array (20). The elements (32) of each sub-array (22) are arranged to minimize the number of such elements (32) that intersect imaginary planes perpendicular to the spiral and passing through the spiral center. Such an orientation of the elements (32) minimizes grating lobes in the antenna pattern.

Abstract: The invention concerns a method and apparatus for cascaded processing of signals in a phased array antenna system in which a plurality of antenna elements are configured as a plurality of sub-arrays. A weighting factor is applied to each of the antenna elements to form a plurality of sub-array beams, each pointed in a selected direction. For each sub-array, an output from each the antenna elements in the sub-array can be combined to produce a sub-array output signal. The sub-array output signals are selectively weighted and combined in a fully adaptive process. Subsequently, the system can estimate an angle-of-arrival direction for a signal-of-interest (“SOI”) and at least one signal-not-of-interest (“SNOI”). Based on this estimating step, the system calculates a new set of weighting factors for controlling one or more of the sub-array beams to improve the signal-to-noise plus interference ratio obtained for the SOI in the array output signal.

Abstract: A phased array antenna includes a circuit board and a balanced, series fed antenna array formed from a plurality of antenna elements positioned in at least two spiral antenna arms on the circuit board. At least one signal feed point is positioned at a center portion of the spiral antenna arms for series feeding the antenna array and conducting transmitted and received signals and breaking up frequency scan and grating lobes.

Abstract: The invention concerns a method and apparatus for cascaded processing of signals in a phased array antenna system in which a plurality of antenna elements are configured as a plurality of sub-arrays. A weighting factor is applied to each of the antenna elements to form a plurality of sub-array beams, each pointed in a selected direction. For each sub-array, an output from each the antenna elements in the sub-array can be combined to produce a sub-array output signal. The sub-array output signals are selectively weighted and combined in a fully adaptive process. Subsequently, the system can estimate an angle-of-arrival direction for a signal-of-interest (“SOI”) and at least one signal-not-of-interest (“SNOI”). Based on this estimating step, the system calculates a new set of weighting factors for controlling one or more of the sub-array beams to improve the signal-to-noise plus interference ratio obtained for the SOI in the array output signal.

Abstract: A phased array antenna includes a circuit board and a balanced, series fed antenna array formed from a plurality of antenna elements positioned in at least two spiral antenna arms on the circuit board. At least one signal feed point is positioned at a center portion of the spiral antenna arms for series feeding the antenna array and conducting transmitted and received signals and breaking up frequency scan and grating lobes.

Abstract: A phased array antenna includes a plurality of antenna elements and a phase shifting device connected to the plurality of antenna elements. The phase shifting device includes a substrate, and a plurality of phase shifters on the substrate. Each phase shifter includes a first conductive portion adjacent the substrate and defining a signal path, and a body adjacent the first conductive portion and comprising a phase shifting material having a controllable dielectric constant for causing a phase shift of a signal being conducted through the signal path. The bodies are laterally spaced apart from one another, and may have a thickness equal to or greater than about 0.002 inches. In forming the phased array antenna, each body is bonded to respective signal paths using production surface mount or similar machines.