Abstract: A power hand tool can include a generally longitudinal housing having a first end and a second end. An indicator can be disposed on the housing. A first and a second jaw member can be arranged at the first end wherein one of the first and second jaw members can rotate relative to the other jaw member. A motor assembly can be disposed in the housing and include an output member arranged at the second end. A sensor can be arranged at the second end and configured to sense an electrical field in proximity thereof. The sensor can generate a signal in response to a sensed electrical field. A controller can receive the sensor signal from the sensor assembly and control operation of the indicator in response thereto.

Abstract: A computing arrangement including a processor and programmable logic. In various embodiments, the arrangement includes an instruction processing circuit coupled to a programmable logic circuit, and a memory arrangement coupled to the instruction processing circuit and to the programmable logic circuit. The instruction processing circuit executes instructions of a native instruction set, and the programmable logic is configured to dynamically translate input instructions to translated instructions of the native instruction set. The translated instructions are stored in a translation cache in the memory arrangement, and the translation cache is managed by the programmable logic. The programmable logic then provides the translated instructions to the instruction processing circuit for execution.

Abstract: Embodiments of the present invention are employ dynamical, nanoscale devices, including memristive connections between nanowires, for constructing parallel, distributed, dynamical computational networks and systems, including perceptron networks and neural networks. In many embodiments of the present invention, neuron-like computational devices are constructed from silicon-based microscale and/or submicroscale components, and interconnected with one another by dynamical interconnections comprising nanowires and memristive connections between nanowires. In many massively parallel, distributed, dynamical computing systems, including the human brain, there may be a far greater number of interconnections than neuron-like computational nodes. Use of dynamical nanoscale devices for these connections results in enormous design, space, energy, and computational efficiencies.

Abstract: In one embodiment of the present invention, a nanoscale latch is implemented by interconnecting an enable line, two control lines, and a pull-down line, when needed, to a signal line carrying encoded binary values to be latched and subsequently output. The enable line is interconnected with the signal line through a field-effect-transistor-like nanoscale junction. Both control lines are interconnected with the signal line through asymmetric-switch nanoscale junctions of like polarities. The pull-down line, when needed, is interconnected with the signal line through a resistive nanoscale junction. Inputting a sequence of signals to the enable and control lines allows a value input from the signal line to be stored and subsequently output to the signal line. In various additional embodiments, an array of nanoscale latches can be implemented by overlaying enable and control lines, and a pull-down line when needed, over a set of parallel nanowires.

Abstract: Various embodiments of the present invention are directed to three-dimensional crossbar arrays. In one aspect of the present invention, a three-dimensional crossbar array includes a plurality of crossbar arrays, a first demultiplexer, a second demultiplexer, and a third demultiplexer. Each crossbar array includes a first layer of nanowires, a second layer of nanowires overlaying the first layer of nanowires, and a third layer of nanowires overlaying the second layer of nanowires. The first demultiplexer is configured to address nanowires in the first layer of nanowires of each crossbar array, the second demultiplexer is configured to address nanowires in the second layer of nanowires of each crossbar array, and the third demultiplexer is configured to supply a signal to the nanowires in the third layer of nanowires of each crossbar array.

Abstract: Reconfigurable logic devices and methods of programming the devices are disclosed. The logic device includes a look-up table (LUT) and at least one storage element configured for sampling LUT output signals. The LUT comprises a plurality of input signals, an array of programmable impedance devices operably coupled to the input signals, and the LUT output signals. Each programmable impedance device in the array includes a first electrode operably coupled to one of the input signal, a second electrode disposed to form a junction wherein the second electrode at least partially overlaps the first electrode, and a programmable material disposed between the first electrode and the second electrode. The programmable material operably couples the first electrode and the second electrode such that each programmable impedance device exhibits a non-volatile programmable impedance. The array may be configured as a one-dimensional or two-dimensional array.

Abstract: A chlorinated rubber composition which is resistant to various fluids such as transmission fluids comprises a blend of a chlorinated polyethylene elastomer, an ethylene acrylic elastomer and/or polyacrylic rubbers, and optionally a chlorosulfonated polyethylene. The rubber composition has many uses such as a tube and generally contains various additives such as fillers, plasticizers, vulcanizing agents, and the like. A heat resistant rubber composition comprises a blend of a chlorinated polyethylene elastomer, an ethylene-acrylic elastomer and/or polyacrylic rubbers, an ethylene-octene copolymer, and an ethylene-propylene-diene terpolymer, and the same can be used as a cover or jacket as on the above chlorinated rubber tube.

Abstract: Reconfigurable logic devices and methods of programming the devices are disclosed. The logic device includes a look-up table (LUT) and at least one storage element configured for sampling LUT output signals. The LUT comprises a plurality of input signals, an array of programmable impedance devices operably coupled to the input signals, and the LUT output signals. Each programmable impedance device in the array includes a first electrode operably coupled to one of the input signal, a second electrode disposed to form a junction wherein the second electrode at least partially overlaps the first electrode, and a programmable material disposed between the first electrode and the second electrode. The programmable material operably couples the first electrode and the second electrode such that each programmable impedance device exhibits a non-volatile programmable impedance. The array may be configured as a one-dimensional or two-dimensional array.

Abstract: A chlorinated rubber composition which is resistant to various fluids such as transmission fluids comprises a blend of a chlorinated polyethylene elastomer, an ethylene acrylic elastomer and/or polyacrylic rubbers, and optionally a chlorosulfonated polyethylene. The rubber composition has many uses such as a tube and generally contains various additives such as fillers, plasticizers, vulcanizing agents, and the like. A heat resistant rubber composition comprises a blend of a chlorinated polyethylene elastomer, an ethylene-acrylic elastomer and/or polyacrylic rubbers, an ethylene-octene copolymer, and an ethylene-propylene-diene terpolymer, and the same can be used as a cover or jacket as on the above chlorinated rubber tube.

Abstract: Various method and system embodiments of the present invention are directed to implementing serial logic gates using nanowire-crossbar arrays with spintronic devices located at nanowire-crossbar junctions. In one embodiment of the present invention, a nanowire-crossbar array comprises a first nanowire and a number of substantially parallel control nanowires positioned so that each control nanowire overlaps the first nanowire. The nanowire-crossbar array includes a number of spintronic devices. Each spintronic device is configured to connect one of the control nanowires to the first nanowire and operate as a latch for controlling signal transmissions between the control nanowire and the first nanowire.

Abstract: A lock set installation apparatus has a pair of hole saw guides which locate a hole to receive door operating members of a lock set. Each hole saw guide has at least one rail member which oppose one another. A lock bolt hole mechanism is movable and coupled with the rails. The lock bolt hole mechanism centers the lock bolt hole onto the door. A locking mechanism locks the hole saw guides with respect to one another to enable cutting of the door.

Abstract: Various embodiments of the present invention are directed to antisymmetric nanowire-crossbar-circuit designs. Antisymmetric nanowire crossbars are composed, in certain embodiments of the present invention, of two or more microregions that receive input signals and two or more microregions that send output signals. Antisymmetric nanowire crossbars may include a nanowire-crossbar network having signal paths that carry signals between one or more of the microregions. The nanowire-crossbar network may also carry signals between external electronic devices and one or more of the microregions. Antisymmetric nanowire crossbars may additionally include two or more structures that supply voltage and ground.

Abstract: The present invention is directed toward a system for forming miter joints including a miter saw and an angle gauge. The miter saw includes a platform with a kerf slot and a pair of arcuate slots. Each arcuate slot includes an associated rail located on the underside of the platform. A fence is coupled to each of the rails such that the fence may be pivoted with respect to the platform. The angle measurement tool is a one-handed tool including spring loaded paddles that measure the angle between intersecting surfaces. The angle measurement tool connects to the miter saw to permit the transfer of the measured angle to the fences.

Abstract: Various embodiments of the present invention are directed to demultiplexers that include tunneling resistor nanowire junctions, and to nanowire addressing methods for reliably addressing nanowire signal lines in nanoscale and mixed-scale demultiplexers. In one embodiment of the present invention, an encoder-demultiplexer comprises a number of input signal lines and an encoder that generates an n-bit-constant-weight-code code-word internal address for each different input address received on the input signal lines. The encoder-demultiplexer includes n microscale signal lines on which an n-bit-constant-weight-code code-word internal address is output by the encoder, where each microscale signal line carries one bit of the n-bit-constant-weight-code code-word internal address.