Abstract: A system for depositing a composite filler material into a channel of a composite structure includes an end-effector configured to extrude a bead of the filler material into the channel. The filler material can comprise a first group of relatively long fibers, a second group of relatively short fibers and a resin. A drive system is configured to move the end-effector relative to the channel, and a position sensor is configured to detect the position of the bead relative to the channel. A controller is configured to operate the drive system in response to the detected position and to operate the end-effector to heat and compress the filler material so as to orient the longer fibers in a substantially longitudinal direction relative to the channel and the shorter fibers in substantially random directions relative to the channel when the bead is extruded into the channel.

Abstract: A modular counterweight system includes a housing, a bracket, and an actuator. The housing is configured to selectively interface with a plurality of counterweights, facilitating incremental adjustment of an overall weight of the modular counterweight system. The bracket is configured to couple the housing to the vehicle, and the housing is at least one of (i) pivotally coupled to the bracket, (ii) extensionally coupled to the bracket, and (iii) translationally coupled to the bracket. The actuator is positioned to selectively reconfigure at least one of the housing and the bracket and thereby change the center of gravity of the modular counterweight system.

Abstract: The article includes a thermoplastic layer having opposing first and second side edges and a first surface bearing male fastening elements. The thermoplastic layer is plastically deformed and has a retardance profile having an average retardance along a line from the first edge to a location 500 micrometers from the first edge and a distance from the first edge where 75% of the average retardance is observed of at least 10 micrometers. In some cases, a distance between the first and second side edges is up to 50 millimeters. In some cases, the article is a fastening tab. The method includes providing a thermoplastic film having opposing first and second side edges, with a distance between the opposing side edges of up to 50 millimeters, and stretching the thermoplastic film to form the thermoplastic layer, which is plastically deformed. The first surface of the thermoplastic film bears male fastening elements.

Abstract: A method for partial redundancy elimination with a fixed number of temporaries includes determining local data values of program code that describe a temporary memory location, a set of registers, and a set of basic blocks. The method determines global data values of the program code based on the determined local data values of the program code. The method removes a first load of the temporary memory location in a first basic block in the program code. The method adds a second load on a first edge from a second basic block out of the set of basic blocks to a third basic block out of the set of basic blocks in the program code. The method performs a register move on a second edge from the third basic block to the second basic block in the program code.

Abstract: A vacuum attachment comprises a base having an upper face and a lower face, and an outer surface and an inner surface. The inner surface defines a first flow passage between the upper face and the lower face. The lower face provides a smooth contact surface. A single orifice extends through the base from the outer surface to the inner surface. The orifice is spaced apart from the lower face.

Abstract: A tooling assembly is provided, for use with a panel defining a tool-side surface and the tool-side surface defining a profile. The tooling assembly includes a base, a plurality of support members fixedly attached to the base, a plurality of frames, and a securing system. The frames each define an upper surface, where each support member is releasably coupled to a corresponding frame by a fastening system. The upper surfaces of the frames are each shaped to correspond with a portion of the profile of the tool-side surface of the panel. The securing system is for providing a suction force configured to releasably secure the panel against the upper surface of the frames.

Abstract: Embodiments disclose a method, computer program product, and system for optimizing computer functions. The embodiment may create a control flow graph from a computer function. The control flow graph may contain an entry block, an exit block, and basic blocks located between the entry block and the exit block. The embodiment may classify each of the basic blocks as an original heavy basic block or an original light basic block. The embodiment may classify the original heavy block, the exit block and each of the basic blocks that are located between each original heavy block and the exit block as a determined heavy block. The embodiment may create light computer functions and heavy computer functions from the computer function. Each heavy computer function contains the basic blocks classified as determined heavy. The light computer functions contains the remaining basic blocks, the exit block and calls to the heavy computer functions.

Abstract: Embodiments disclose a method, computer program product, and system for optimizing computer functions. The embodiment may create a control flow graph from a computer function. The control flow graph may contain an entry block, an exit block, and basic blocks located between the entry block and the exit block. The embodiment may classify each of the basic blocks as an original heavy basic block or an original light basic block. The embodiment may classify the original heavy block, the exit block and each of the basic blocks that are located between each original heavy block and the exit block as a determined heavy block. The embodiment may create light computer functions and heavy computer functions from the computer function. Each heavy computer function contains the basic blocks classified as determined heavy. The light computer functions contains the remaining basic blocks, the exit block and calls to the heavy computer functions.

Abstract: Embodiments disclose a method, computer program product, and system for optimizing computer functions. The embodiment may create a control flow graph from a computer function. The control flow graph may contain an entry block, an exit block, and basic blocks located between the entry block and the exit block. The embodiment may classify each of the basic blocks as an original heavy basic block or an original light basic block. The embodiment may classify the original heavy block, the exit block and each of the basic blocks that are located between each original heavy block and the exit block as a determined heavy block. The embodiment may create light computer functions and heavy computer functions from the computer function. Each heavy computer function contains the basic blocks classified as determined heavy. The light computer functions contains the remaining basic blocks, the exit block and calls to the heavy computer functions.

Abstract: Absorbent article including a chassis and fastening tab. The fastening tab includes a carrier, a first fastener having first male fastening elements, and a second fastener. The second fastener includes a backing with first and second opposing surfaces, with second male fastening elements on the first surface. A first portion of the second surface of the backing is connected to the carrier, and a second portion of the second surface of the backing is attached to the topsheet side of the chassis. The carrier is attached to the backsheet side of the chassis. Some fastening laminates, before attachment to the article, have the second portion of the second fastener folded over to face the first portion of the second fastener. Other laminates have the second fastener positioned with its first surface toward the carrier and attached to the carrier with a film.

Abstract: A method and apparatus comprising a structure and a connector. The structure may have a number of walls forming a channel with a first opening and a second opening. The connector may be associated with the first opening. The connector may be configured to change a size of the first opening.

Abstract: A wetness sensor includes a substrate that carries a tuned RF circuit. The circuit includes a conductive pattern applied to the substrate, a capacitor, and a jumper all disposed on a same side of the substrate. The conductive pattern includes an inductive coil, and an inner and outer terminus. The jumper electrically couples the inner terminus to the outer terminus. The jumper also includes a frangible link which, when contacted by a target fluid, produces a drastic change in the operation of the RF circuit. The drastic change can be interpreted by a remote reader as a “wet” condition. Contact of the frangible link by the target fluid may change the impedance or resistance of the RF circuit by at least a factor of 5, 10, 100, or more, and/or may cause the frangible link to disintegrate to produce an open circuit, and/or may substantially render the RF circuit inoperative.

Abstract: A wetness sensor includes a self-supporting substrate and an electrically conductive trace carried by the substrate. The trace is patterned to provide at least a portion of a tuned RF circuit, which may be disposed on only one side of the substrate and characterized by an impedance or resistance. The trace is not self-supporting. The substrate is adapted to dissolve, swell, or otherwise degrade when contacted by a target fluid. Such degradation produces a drastic change in the operation of the RF circuit, which can be interpreted by a remote reader as a “wet” condition. Contact of the substrate by the target fluid may change the impedance or resistance of the RF circuit by at least a factor of 5, 10, 100, or 1000, and/or may cause the trace to disintegrate so as to provide the RF circuit with an open circuit, and/or may substantially render the RF circuit inoperative.

Abstract: A wetness sensor includes a self-supporting substrate and an electrically conductive trace carried by the substrate. The trace is patterned to provide at least a portion of a tuned RF circuit, which may be disposed on only one side of the substrate and characterized by an impedance or resistance. The trace is not self-supporting. The substrate is adapted to dissolve, swell, or otherwise degrade when contacted by a target fluid. Such degradation produces a drastic change in the operation of the RF circuit, which can be interpreted by a remote reader as a “wet” condition. Contact of the substrate by the target fluid may change the impedance or resistance of the RF circuit by at least a factor of 5, 10, 100, or 1000, and/or may cause the trace to disintegrate so as to provide the RF circuit with an open circuit, and/or may substantially render the RF circuit inoperative.

Abstract: A modular counterweight system includes a housing, a bracket, and an actuator. The housing is configured to selectively interface with a plurality of counterweights, facilitating incremental adjustment of an overall weight of the modular counterweight system. The bracket is configured to couple the housing to the vehicle, and the housing is at least one of (i) pivotally coupled to the bracket, (ii) extensionally coupled to the bracket, and (iii) translationally coupled to the bracket. The actuator is positioned to selectively reconfigure at least one of the housing and the bracket and thereby change the center of gravity of the modular counterweight system.

Abstract: Embodiments disclose a method, computer program product, and system for optimizing computer functions. The embodiment may create a control flow graph from a computer function. The control flow graph may contain an entry block, an exit block, and basic blocks located between the entry block and the exit block. The embodiment may classify each of the basic blocks as an original heavy basic block or an original light basic block. The embodiment may classify the original heavy block, the exit block and each of the basic blocks that are located between each original heavy block and the exit block as a determined heavy block. The embodiment may create light computer functions and heavy computer functions from the computer function. Each heavy computer function contains the basic blocks classified as determined heavy. The light computer functions contains the remaining basic blocks, the exit block and calls to the heavy computer functions.

Abstract: Embodiments disclose a method, computer program product, and system for optimizing computer functions. The embodiment may create a control flow graph from a computer function. The control flow graph may contain an entry block, an exit block, and basic blocks located between the entry block and the exit block. The embodiment may classify each of the basic blocks as an original heavy basic block or an original light basic block. The embodiment may classify the original heavy block, the exit block and each of the basic blocks that are located between each original heavy block and the exit block as a determined heavy block. The embodiment may create light computer functions and heavy computer functions from the computer function. Each heavy computer function contains the basic blocks classified as determined heavy. The light computer functions contains the remaining basic blocks, the exit block and calls to the heavy computer functions.

Abstract: A method, executed by a computer, for splitting live register ranges includes identifying one or more H pathways comprising one or more H nodes having high register pressure, identifying an L pathway consisting of two or more L nodes, and inserting register splitting instructions for each symbolic register that is live in both the one or more H pathways and the L pathway, wherein the register splitting instructions are inserted at a starting node of the one or more H pathways. A computer program product and computer system corresponding to the above method are also disclosed herein.

Abstract: A method, executed by a computer, for splitting live register ranges includes identifying one or more H pathways comprising one or more H nodes having high register pressure, identifying an L pathway consisting of two or more L nodes, and inserting register splitting instructions for each symbolic register that is live in both the one or more H pathways and the L pathway, wherein the register splitting instructions are inserted at a starting node of the one or more H pathways. A computer program product and computer system corresponding to the above method are also disclosed herein.

Abstract: A system for depositing a composite filler material into a channel of a composite structure includes an end-effector configured to extrude a bead of the filler material into the channel. The filler material can comprise a first group of relatively long fibers, a second group of relatively short fibers and a resin. A drive system is configured to move the end-effector relative to the channel, and a position sensor is configured to detect the position of the bead relative to the channel. A controller is configured to operate the drive system in response to the detected position and to operate the end-effector to heat and compress the filler material so as to orient the longer fibers in a substantially longitudinal direction relative to the channel and the shorter fibers in substantially random directions relative to the channel when the bead is extruded into the channel.