Abstract: A method of forming a composite article may generally comprise forming a mixture of (i) a reactant gas stream comprising hydrogen and methyltrichlorosilane and (ii) solid silicon carbide particles; heating a carbon substrate in the reactor; heating the mixture of the reactant gas stream and solid silicon carbide particles to decompose the methyltrichlorosilane to produce silicon carbide material without causing the solid silicon carbide particles to react and injecting the heated mixture into the reactor; co-depositing the silicon carbide material and the solid silicon carbide particles onto the heated carbon substrate in the reactor to produce a CVD matrix comprising the silicon carbide material and the solid silicon carbide particles by chemical vapor deposition on the heated carbon substrate; post-treating the carbon substrate having the CVD matrix coating in a furnace; and cooling and removing the carbon substrate from the CVD matrix to form the transparent composite article.

Abstract: A method of forming a composite article may generally comprise forming a mixture of (i) a reactant gas stream comprising hydrogen and methyltrichlorosilane and (ii) solid silicon carbide particles; heating a carbon substrate in the reactor; heating the mixture of the reactant gas stream and solid silicon carbide particles to decompose the methyltrichlorosilane to produce silicon carbide material without causing the solid silicon carbide particles to react and injecting the heated mixture into the reactor; co-depositing the silicon carbide material and the solid silicon carbide particles onto the heated carbon substrate in the reactor to produce a CVD matrix comprising the silicon carbide material and the solid silicon carbide particles by chemical vapor deposition on the heated carbon substrate; post-treating the carbon substrate having the CVD matrix coating in a furnace; and cooling and removing the carbon substrate from the CVD matrix to form the transparent composite article.

Abstract: A method of forming a composite article may generally comprise forming a mixture of (i) a reactant gas stream comprising hydrogen and methyltrichlorosilane and (ii) solid silicon carbide particles; heating a carbon substrate in the reactor; heating the mixture of the reactant gas stream and solid silicon carbide particles to decompose the methyltrichlorosilane to produce silicon carbide material without causing the solid silicon carbide particles to react and injecting the heated mixture into the reactor; co-depositing the silicon carbide material and the solid silicon carbide particles onto the heated carbon substrate in the reactor to produce a CVD matrix comprising the silicon carbide material and the solid silicon carbide particles by chemical vapor deposition on the heated carbon substrate; post-treating the carbon substrate having the CVD matrix coating in a furnace; and cooling and removing the carbon substrate from the CVD matrix to form the transparent composite article.

Abstract: Embodiments of a flight vehicle are provided, as are embodiments of a method for manufacturing a flight vehicle. In one embodiment, the flight vehicle includes a solid-propellant rocket motor, control circuitry, and an electrically-interconnective support structure. The electrically-interconnective support structure includes a load-bearing frame and a plurality of electrical conductors embedded within the load-bearing frame. The solid-propellant rocket motor is mounted to the load-bearing frame, and the plurality of electrical conductors embedded within the frame electrically couples the solid-propellant rocket motor to the control circuitry.

Abstract: A composite interconnect assembly includes a body structure formed from a composite material (e.g., a carbon graphite material) with one or more conductive traces embedded therein (e.g., a copper or copper alloy). One or more contact regions are provided such that the conductive traces are exposed and are configured to mechanically and electrically connect to one or more electronic components. The body structure may have a variety of shapes, including planar, cylindrical, conical, and the like.

Abstract: A composite interconnect assembly includes a body structure formed from a composite material (e.g., a carbon graphite material) with one or more conductive traces embedded therein (e.g., a copper or copper alloy). One or more contact regions are provided such that the conductive traces are exposed and are configured to mechanically and electrically connect to one or more electronic components. The body structure may have a variety of shapes, including planar, cylindrical, conical, and the like.

Abstract: Embodiments of a flight vehicle are provided, as are embodiments of a method for manufacturing a flight vehicle. In one embodiment, the flight vehicle includes a solid-propellant rocket motor, control circuitry, and an electrically-interconnective support structure. The electrically-interconnective support structure includes a load-bearing frame and a plurality of electrical conductors embedded within the load-bearing frame. The solid-propellant rocket motor is mounted to the load-bearing frame, and the plurality of electrical conductors embedded within the frame electrically couples the solid-propellant rocket motor to the control circuitry.

Abstract: A composite interconnect assembly includes a body structure formed from a composite material (e.g., a carbon graphite material) with one or more conductive traces embedded therein (e.g., a copper or copper alloy). One or more contact regions are provided such that the conductive traces are exposed and are configured to mechanically and electrically connect to one or more electronic components. The body structure may have a variety of shapes, including planar, cylindrical, conical, and the like.

Abstract: A method and system for identifying anomalous cells includes an imaging subsystem to generate a track file from collected images of cells, a image processing subsystem to extract features from the track file and generate feature sets for particular cells, and a discrimination subsystem to generate a probabilistic belief function from the feature sets to determine a probability that at least some of the cells are anomalous. The images may include sample cells from a tissue sample. In embodiments, the imaging subsystem may collect images from photographs and may also collect images from a microscope. In embodiments, the discrimination subsystem may perform both supervised and unsupervised training to update the belief functions learning from known anomalous cells and cells with know anomalous features to enhance its accuracy over time.

Abstract: A position encoder uses a track encoded with a pattern of bit-widths in accordance with a sequence. The sequence may be any sequence having unique subsequences, and may be a pseudo-random noise (PRN) sequence such that each N-bit subsequence occurs only once on the track. Sensors detect transitions between the bits and bit-widths as the track moves with respect to the sensors to provide in-phase and quadrature-phase pick-off signals. The pickoff signals are summed and absolute value thresholded. The absolute value thresholded sum signal is sampled when the quadrature pairs are in the “00” or “11” quadrants, and latched when the sum signal goes high to distinguish between wide and narrow bit widths. The latch is shifted into a shift data register for use in determining the position of the encoder track. In the case of a PRN sequence having a length of 2N bits, the position may be an absolute position when the number of valid bits in the shift data register is at least N.

Abstract: A method and system for identifying anomalous cells includes an imaging subsystem to generate a track file from collected images of cells, a image processing subsystem to extract features from the track file and generate feature sets for particular cells, and a discrimination subsystem to generate a probabilistic belief function from the feature sets to determine a probability that at least some of the cells are anomalous. The images may include sample cells from a tissue sample. In embodiments, the imaging subsystem may collect images from photographs and may also collect images from a microscope. In embodiments, the discrimination subsystem may perform both supervised and unsupervised training to update the belief functions learning from known anomalous cells and cells with know anomalous features to enhance its accuracy over time.

Abstract: A position encoder uses a track encoded with a pattern of bit-widths in accordance with a sequence. The sequence may be any sequence having unique subsequences, and may be a pseudo-random noise (PRN) sequence such that each N-bit subsequence occurs only once on the track. Sensors detect transitions between the bits and bit-widths as the track moves with respect to the sensors to provide in-phase and quadrature-phase pick-off signals. The pickoff signals are summed and absolute value thresholded. The absolute value thresholded sum signal is sampled when the quadrature pairs are in the “00” or “11” quadrants, and latched when the sum signal goes high to distinguish between wide and narrow bit widths. The latch is shifted into a shift data register for use in determining the position of the encoder track. In the case of a PRN sequence having a length of 2N bits, the position may be an absolute position when the number of valid bits in the shift data register is at least N.