Abstract: A fabric for use with a system for monitoring prescribed body functions comprising an elastic fabric, adapted to be carried by a torso, which is stretchable in its longitudinal direction so as to expand and contract in response to body movement and size. The carrier includes at least one conductive and inelastic yarn arranged longitudinally of and located between upper and lower surfaces. The conductive yarn is arranged in sinusoidal configurations longitudinally of the fabric. The conductive yarn breaks through one of the outer surfaces at a selected breakout along the length of the fabric. The conductive yarn is cut to present at least one exposed end above the one outer surface. A monitoring unit, which includes a connector and a sensor, is secured with the one outer surface of the fabric at the breakout with the connector being united with the at least one exposed end of the conductive yarn.

Abstract: A fabric for use with a system for monitoring prescribed body functions comprising an elastic fabric, adapted to be carried by a torso, which is stretchable in its longitudinal direction so as to expand and contract in response to body movement and size. The carrier includes at least one conductive and inelastic yarn arranged longitudinally of and located between upper and lower surfaces. The conductive yarn is arranged in sinusoidal configurations longitudinally of the fabric. The conductive yarn forms a breakout through one of the outer surfaces, at selected locations along the length of the fabric, forming opposed exposed ends above the surface. A monitoring unit, which includes a connector and a sensor, is secured with the one surface at the breakout with the connector being united with the exposed ends of the conductive yarn. The fabric acts to maintain the monitoring unit in a desired stationary position allowing the sensor to sense signals emitted from the torso and transmit these senses signals.

Abstract: A connector assembly is disclosed for interconnecting high speed data transmission cables across an interface panel to an external circuit. A first pin array of conductive pins is carried by an input face and a corresponding second pin array of conductive pins is carried by an output face of a panel connector. An array of conductive sockets corresponding to the second pin array is carried by a plug front of a plug connector for receiving the second array of pins when connectors are mated together. A third pin array of conductive pins is carried by plug back corresponding to the first pin array. In this manner, a first set of transmission cables electrically connected to the first pin array of the panel connector is electrically connected to a second set of transmission cables connected to the third pin array of the plug connector.

Abstract: The support bracket and cable assembly of this invention allows an internal circuit board of a host computer to be directly connected to a plurality of peripheral devices using a plurality of interface cables through a first port of an input/output frame. A rigid compound bracket has two bracket elements with cutouts to form cylindrical openings through which the interface cables pass. The cylindrical openings or channels have at least one collar that grips and holds the interface cables within a single port of an input/output (I/O) frame of an enclosure of the host computer. Therefore, interface cables to go directly from the internal circuit board to the peripheral devices without intermediate connectors at the I/O frame. The compound bracket is attached to the I/O frame by a bracket mount arrangement. A grounding interface is provided for the peripheral devices as the interface cables pass through the cylindrical openings in the compound bracket.

Abstract: The high-speed electrical transmission cable connector assembly of this invention includes an electrical connector having a connector backshell with an internal cavity for receiving an electrical insert to interface with an electrical interface device. An adequate amount of space is provided by the internal cavity within the backshell for routing wires of the transmission cable through a neck in an entrance side of the backshell to terminate within the insert. The backshell has a truncated side and a short lateral side for saving space and weight of the electrical connector. A grounding terminal is carried within the internal cavity of the backshell adjacent to the neck on a short neck side for grounding wires within a short distance inside the backshell. An attachment and release mechanism is provided for connecting and disconnecting the interface device to the electrical insert within the backshell.

Abstract: A woven wire harness assembly for use in restricted areas of varying sizes. The harness assembly includes a fabricate cable carrying a plurality of insulated conductor groups. The cable is formed of warp yarns woven with a weft yarn to form a trunk portion and a tube portion. Both the trunk portion and the tube portion terminate with a breakout area. The trunk portion includes a plurality of cells while the tube portion has only a single cell. The plurality of insulated conductors extend continuously along the length of harness assembly through the individual cells to finally consolidate and extend through the single cell. The cable is woven at a density which provides approximately 90% cover providing mechanical and thermal insulation for the insulated conductors.

Abstract: A woven transmission cable formed of a plurality of conductor wires arranged in side-by-side relationship forming an array which extends along a single plane. Coating the conductor wires with a self lubricating insulating material and separating them with warp yarns which are located between adjacent ones thereof. Weaving a weft yarn, formed also of a self lubricating material, to pass alternately over and under the warp yarns and the wires of the array, forming a woven structure in which the wires are capable of longitudinal adjustment relative to the warp yarns and the weft yarns. The longitudinal adjustment allows the cable to be shaped into an arcuate configuration while maintaining the wires along a single plane.

Abstract: A versatile electrical connector housing 12 with strain relief, includes a first housing section 26 and a second housing section 30. First back ridge 44 being offset from and in combination with a second back ridge 48 provide a strain relief. A vertical passage 50 in combination with a horizontal passage 52 allows an electrical transmission cable 16 to enter into the electrical connector within the profile of the electrical connector.

Abstract: A coax retention comb adapted to be fittingly engaged within an interior area of a back shell of a coax assembly. The comb includes a plurality of slots formed across its top and bottom surfaces, the slots are vertically offset from each other and are tapered inwardly from rear to front which are adapted to receive an insulated coaxial wire. The coaxial wire has a diameter slightly larger that the inward tapered end of the slots so that the tapered ends are expanded where the wires are inserted therein. The interior area of the back shell is of a size which forces the comb back into its original configuration when the comb is fitted therein. This causes the inwardly tapered ends of the slots to bite into the insulation of the wires which fixedly position the wires relative to the comb.

Abstract: A cable assembly (A) is disclosed for a logic analyzer which comprises a flat woven cable (14) having an analyzer connector (18) and a probe connector (22). The analyzer connector includes a printed circuit board (32) and the probe connector includes a printed circuit board (34). Resistor-capacitor networks (D, E) are carried on respective PC board (32, 34) for extending the effective bandwidth of the cable assembly. A cable assembly (A") is disclosed having a low capacitance provided by high gauge signal conductors (92) and increased center-to-center spacing between the signal conductor and exclusively associated ground wires (94a, 94b). Resistor netowkrs (D', E') provide a high input resistance to the cable assembly. An interface shroud (B) connects terminal (C) of probe leads (10) to probe connector (22). A plurality of exterior grooves (54) are formed on an upper wall (44) of interface shroud (B) which receive locking arm (62) of terminal body (60).

Abstract: A structure multi-layer fabric (A) is disclosed having a prescribed weave pattern and mesh which provides uniform flexibility and which can be used as structural fabric or impregnated with a resin in a structural composite. The flexibility of the fabric facilitates conforming of the fabric to a desired shape. The rising and sinking warp yarns in the warp and weft directions facilitate effective impregnation by defining trough-like structures in the fabric, as well as enhancing the fabric flexibility. The fabric is characterized as having (N) layers, 2N basic warp yarns woven in a 2N yarn repeat, and 2N-2) basic weft yarns woven in a (2N-2) yarn repeat. In the illustrated embodiment, there are 10 basic weft yarn picks (60,62,64,66,68,70,72,74,76,78) and twelve basic warp yarns (34,36,38,40,42,44,46,48,50,52,54,56) woven in 6 layers (D,E,F,G,H,I). Warp yarns (B) and weft yarns (C) rise and sink in the fabric between outer face (30) and outer face (32).

Abstract: A high density multi-conductor ribbon cable (A, A', 40, 56', 65, 65', 90, 90') is disclosed having a variable width and variable center spacing (X) of conductors (12) along the cable length. The spacing of conductors (12) is determined by the vertical position of a tapered reed (B) and the cable may be extruded (40) or woven (56). Variations in the width and spacing of the signal conductors may be had to match mechanical and/or electrical characteristics of associated terminal connectors (22, 68, 68') and input and output devices (26, 28).

Abstract: A woven webbing sling (A) for hoisting industrial cargo is disclosed which includes woven outer plies (28,29) which include woven warp yarns (22,24 and 30,32) interwoven with a weft yarn (26). Plies of filler material (35) extend between the outer plies. Protective edges (18,20) include vinyl coated yarns (B) having elongation properties generally equal to that of the woven warp yarns to resist cutting of the sling.

Abstract: A woven electrical transmission cable and method for the rapid repair of a defective electrical cable in an aircraft and the like is disclosed. A woven electrical transmission cable (A) for rapid repair includes longitudinal warp anchor cords (B) interwoven with warp and weft yarns (38, 40). The warp and weft yarns are woven in a prescribed pattern in which elongated electrical conductors (36) are bound in individual cells (22, 24, 26, 28, 30, 32). A prescribed number of conductors (36) is included in each cell which may be easily traced and identified at opposing ends of the cable within the individual cells. This insures reliable termination at the ends of the cable. In accordance with the method, cable (A) is bonded to the skin (12a) of an aircraft adjacent access openings (14, 16) to repair a defective cable (11a ) which has been damaged by a bullet or shell through hole (11). Woven electrical repair cable (A) by-passes defective cable (11a) and may be terminated through the access openings.

Abstract: A multilayer woven high density electrical transmission cable (A) is disclosed including a first woven cable layer (D) and a second woven cable layer (E) bound together by warp bindings (24) as integral cable structure. Signal conductors (16) and ground conductors (18) extend in the warp direction in cable layer (D). Signal conductors (26) and ground conductors (28) extend in the warp direction in cable layer (E). Signal conductors (16 and 26) are broken out of their respective cable layers either on opposite sides, breakout sections (B,B'), or at the same sides, breakout section (B") as required for a prescribed program termination. All of the ground conductors (18 or 28) of one cable layer cross over to the side of the other cable layer so that one-hundred percent of the ground conductors (18 and 28) are on the same side at the breakout section for termination. The density of the signal conductors is doubled for a given cable width while affording signal identification for a prescribed termination program.

Abstract: A method and woven structure for terminating a woven cable are disclosed wherein termination sections B are woven in continuous cabling 10 and spaced apart to define sections of individual woven cable A. In termination section B, ground wires 14 are floated above the plane of the woven cable and outside of the weave pattern. Signal conductors 12 are woven through the cabling with center-lines of adjacent conductors being fixed by the weave pattern. In the method, the ground wires are severed and terminated to a common bus bar 20. Next, an insulation displaceable connector C, of the type typically used with extruded cabling, is inserted in the weave portion 18 whereby the prongs of the insulation displaceable connector pierce and displace the insulation on the signal conductors 12. Bus bar 20 is electrically connected to a pin 24 of the insulation displaceable connector by means of a pigtail or other wire 26.

Abstract: A crimp contact and method for terminating discrete electrical conductor wires with a printed circuit board includes a crimp contact A having a crimp barrel (10) in which wire (16) is crimped. A solder post (24) extends from a widened circular flange (22) which is integral with the crimp barrel. Spacer block (20) spaces circular flange (22) above plated through hole (32) so that a space is provided which may be completely filled with solder. A pair of quarter round seating sections (28 and 30) are formed on opposing surfaces (24a and 24c) of solder post (24). The remaining periphery of solder post is open at (42) to facilitate upward and complete flow of the solder.

Abstract: A woven high speed electrical transmission cable and method are disclosed in which an insulation displaceable connector (24) is utilized to terminate flat woven cable (10). A plurality of signal conductors (12) are arranged generally side by side in the cable extending longitudinally in the warp direction. Warp elements (A,14) and weft elements (16) are interwoven with signal conductors (12) to bind the signal conductors in a prescribed weave pattern. The warp elements are polymeric mono warp strands (A) which include a central reinforcing core (40) of reinforcing fibers (20). A soft pliable polymeric material (22) encapsulates reinforcing fibers (20). Polymeric mono strands have a well defined diametric dimension to accurately fix the lateral spacing of signal conductors (12) in cable (10).

Abstract: A transitional printed circuit board (10) is disclosed for terminating four multiconductor flat electrial transmission cables (44, 46, 48, 50) wherein only a single substrate (12) is utilized. A first electrical plane (A) is formed on one side of the substrate and a second electrical plane (B) is formed on an opposing side of the substrate with the substrate material in between serving as an insulator. Each electrical plane includes a ground plane (26, 41) and spaced electrical lands (14, 16, 32 ,34). Plated through holes (24) allow the lands from opposing sides to be connected to the opposite side for programmed termination. A series of electrical pads (22, 42) provide for termination to the prongs (52a, 52b) of terminal connector (52). Two cables may be terminated on each electrical plane of the printed circuit board by terminating ground wires of the first cable to the ground plane (26, 41), and the signal wires to the electrical lands (14, 32).

Abstract: A woven electrical transmission cable is disclosed having a controlled impedance and reduced signal interference characteristic in which the density of the signal conductors may be increased without widening the configuration of the cable. The cable (A, F, K) is woven in a tubular configuration wherein the signal conductors (10, 30, 34) are arranged and woven about the periphery of the cable with a vertical spacing component between the conductors. The signal conductors are arranged with ground conductors (12, 32, 36) on each side thereof in the form of clusters (D, E, G, H) in strata about the periphery of the cable. In a preferred form the cable (F, K) is woven in a flattened oval configuration wherein the clusters of conductors are arranged in spaced layers which are generally parallel. In practice, noisy lines and quiet lines may be placed in opposed layers for maximum reduction of signal interference.