Abstract: Disclosed herein is a laser processing apparatus that includes a cassette table for placing thereon a cassette in which a plurality of workpieces are accommodated, a carrying-out unit for carrying out the workpiece from the cassette placed on the cassette table, an X-axis direction moving unit for processing feed of a chuck table in the X-axis direction, a Y-axis direction moving unit for indexing feed of the chuck table in a Y-axis direction orthogonal to the X-axis direction, and a laser beam applying unit having a focusing unit for applying a laser beam to the workpiece held on the chuck table.

Abstract: An imaging apparatus includes a front lens group, including a reflector element and a front lens element on the object side thereof, and a rear lens group; a support member, fixed to a fixed member that supports the reflector element, including a spherical-swinging operation support positioned behind the reflection surface of the reflector element and supporting a movable member supporting the front lens element to spherically swing about a predetermined point, a rotation preventer preventing the movable member from rotating about the optical axis of the front lens element, a detector supporter, and a mounting portion mounted to the fixed member; an actuator which drives the movable member to spherically swing the movable member in response to vibrations applied to the imaging optical system; a detector detecting positional variations of the movable member; and an adjuster which adjusts the position of the mounting portion relative to the fixed member.

Abstract: Beginning with a sheet of optically transparent material, one may fabricate a great many shaped optical wafers, each in the form of a thin and essentially flat piece of optical material having a narrow cross-sectional width relative to length, and a sharply narrowed tip at one end. The fabrication process involves passing a sheet of optically transparent material through one or more operational steps wherein cutting, shearing, embossing, microperforating, or a combination thereof is performed. The fabrication process may further include a cladding operation, a tip texturing operation, and an analyte-reactive reagent deposition operation. The completed optical wafers are separated and each may be mounted into a user-operated device along with systems for educing a fluid sample to be expressed from a living organism, for bringing the tip of the optical wafer into contact with the fluid sample, and for illuminating and assaying the fluid sample.

Abstract: Apparatus for acoustic measurement in a downhole environment to enable high quality measurements to be obtained in difficult logging conditions are disclosed. An example apparatus includes a downhole tool having a body with a plurality of transmitters located on the body. A receiver is located on the body a distance from the transmitters and an attenuator section is integrally formed on the body between at least one transmitter and the receiver.

Abstract: According to one embodiment, a testing device of a turbine blade includes: a non-compressive elastic medium brought into close contact with a platform of the turbine blade in a state fastened to a turbine rotor; a probe which has piezoelectric elements arranged in an array and transmits ultrasound waves toward a fastening portion of the turbine blade through the elastic medium and receives echo waves; and a display portion for imaging an internal region of the fastening portion on the basis of the echo waves and displaying the same.

Abstract: Beginning with a sheet of optically transparent material, one may fabricate a great many shaped optical wafers, each in the form of a thin and essentially flat piece of optical material having a narrow cross-sectional width relative to length, and a sharply narrowed tip at one end. The fabrication process involves passing a sheet of optically transparent material through one or more operational steps wherein cutting, shearing, embossing, microperforating, or a combination thereof is performed. The fabrication process may further include a cladding operation, a tip texturing operation, and an analyte-reactive reagent deposition operation. The completed optical wafers are separated and each may be mounted into a user-operated device along with systems for educing a fluid sample to be expressed from a living organism, for bringing the tip of the optical wafer into contact with the fluid sample, and for illuminating and assaying the fluid sample.

Abstract: An imaging apparatus includes a front lens group having a front lens element and a reflector, in that order from an object side. The reflector includes a reflection surface which reflects light rays, from the front lens element, toward a different direction; a rear lens group positioned closer to an image plane than the front lens group, the imaging apparatus performs an image-stabilizing operation by driving the front lens element, a movable frame holding the front lens element; a support member supporting the reflector and is immovable relative to an optical axis of the front lens element, in a reference state; and a support mechanism which supports the movable frame to spherically swing about a spherical-swinging center, positioned on an extension of the optical axis of the front lens element extending behind an underside of the reflection surface of the reflector.

Abstract: Disclosed herein is a laser processing apparatus including first and second laser mechanisms, a laser oscillator for oscillating an original laser beam, an optical system for branching the original laser beam into first and second laser beams, and first and second operation panels for respectively setting first and second processing conditions for the first and second laser mechanisms. The first and second laser mechanisms include first and second chuck tables for holding first and second workpieces, first and second X moving units for moving the first and second chuck tables in an X direction, first and second Y moving units for moving the first and second chuck tables in a Y direction perpendicular to the X direction, and first and second focusing units for focusing the first and second laser beams to the first and second workpieces held on the first and second chuck tables, respectively.

Abstract: A laser processing apparatus includes a first chuck table for holding a first workpiece, moving units for moving the first chuck table in X and Y directions, and a first focusing unit for focusing a first laser beam to the first workpiece. A second chuck table holds a second workpiece. Other moving units move the second chuck table in the X direction and Y directions, and a second focusing unit focuses a second laser beam to the second workpiece. A laser oscillator produces an original laser beam, and an optical system branches the original laser beam into the first laser beam and the second laser beam, and leads the first and second laser beams to the first and second focusing units, respectively.

Abstract: An imprint apparatus according to one embodiment includes a contact processing unit and a defect determination unit. The contact processing unit brings a template pattern formed on a front surface of a template into contact with resist placed on a substrate. The defect determination unit determines a defect in an imprint process, on the basis of force which is generated from at least one of the template, the resist, and the substrate, during the imprint process.

Abstract: According to one embodiment, a neuron learning type integrated circuit device includes neuron cell units. Each of the neuron cell units includes synapse circuit units, and a soma circuit unit connected to the synapse circuit units. Each of the synapse circuit units includes a first transistor including a first terminal, a second terminal, and a first control terminal, a second transistor including a third terminal, a fourth terminal, and a second control terminal, a first condenser, one end of the first condenser being connected between the second and third terminals, and a control line connected to the first and second control terminals. The soma circuit unit includes a Zener diode including an input terminal and an output terminal, the input terminal being connected to the fourth terminal, and a second condenser, one end of the second condenser being connected between the fourth terminal and the input terminal.

Abstract: An imaging optical system includes a bending optical element which bends an object-emanating light bundle, a post-bending lens system on a post-bending optical axis defined by the bending optical element, and an image sensor. An effective optical surface of a large-diameter lens element, having a greatest axial light bundle effective radius, is formed into a non-circular shape by making a length of the effective optical surface from the post-bending optical axis toward a side opposite from the object side smaller than the axial light bundle effective radius, with reference to the axial light bundle effective radius lying on a plane which extends orthogonal to a plane including both the post-bending optical axis and a pre-bending optical axis of the imaging optical system and includes the post-bending optical axis.

Abstract: A water repellent liquid for forming water repellent film. The liquid is provided containing: fluoroalkylsilane compound represented by general formula 1 where “m” is an integer between 2 and 7, “n” is an integer between 1 and 5, “X” is mutually independently at least one group selected from the group consisting of alkoxy group, chloro group, isocyanate group and hydroxyl group, and “p” is an integer between 1 and 3; silicon compound represented by general formula 2 R12SiY2 ??2 where “R1” mutually independently represents a C1-C20 hydrocarbon group, “Y” mutually independently represents at least one group selected from the group consisting of alkoxy group, chloro group, isocyanate group and hydroxyl group, and “R1” may be a branched hydrocarbon group or a cyclic hydrocarbon group; organic solvent; water; and acid. In this liquid the mass ratio of the fluoroalkylsilane compound to the silicon compound is between 1:0.1 and 1:20.

Abstract: Annular shaped sensor devices are disclosed that comprise an axial array of wedge-shaped optical sensors having tips oriented inward, with analyte-reactive reagents resident on a portion of the tip surfaces. These annular optical sensor devices are cut out from sheets or continuous sheeting of flat optically transparent polymers, and are preferably coated with a cladding material on major surfaces, other than the tips, so as to function as optical light guides. The tips are preferably beveled before deposition of the analyte-reactive reagent. The tips are amenable to deflection movement independently of one another. A method of making the annular optical sensor devices is disclosed and a method of using such devices in the analysis of biological fluid droplets is also disclosed.

Abstract: Polymeric membranes with greatly enhanced selectivities, permeation rates, and separation factors were formed by exposure of glassy polymers having high fractional free volume to an oxidizing gas plasma. Thusly treated membranes showed selectivities for low molecular weight alcohols (methanol, ethanol) versus water that were greater than 1.0, being as high as 10 to 15 during pervaporation. Mass transport rates for methanol reached the range of 500 to 1000 moles/m2-hr or higher in some instances which is more characteristic of vacuum membrane distillation than pervaporation. Devices made from plasma-treated polymethylpentene membranes were particularly effective concentrating alcohols selectively by evaporative methods, i.e. pervaporation/vacuum membrane distillation.

Abstract: Beginning with a sheet of optically transparent material, one may fabricate a great many shaped optical wafers, each in the form of a thin and essentially flat piece of optical material having a narrow cross-sectional width relative to length, and a sharply narrowed tip at one end. The fabrication process involves passing a sheet of optically transparent material through one or more operational steps wherein cutting, shearing, embossing, microperforating, or a combination thereof is performed. The fabrication process may further include a cladding operation, a tip texturing operation, and an analyte-reactive reagent deposition operation. The completed optical wafers are separated and each may be mounted into a user-operated device along with systems for educing a fluid sample to be expressed from a living organism, for bringing the tip of the optical wafer into contact with the fluid sample, and for illuminating and assaying the fluid sample.

Abstract: An imaging apparatus includes a front lens group having a front lens element and a reflector; a support member supporting the reflector; a support mechanism supporting the movable frame, supporting the front lens element, to spherically swing about a center positioned on an extension of the front lens element optical axis behind a reflection surface of the reflector; and a permanent magnet and a coil as an actuator which performs image stabilization by driving the movable frame in response to vibrations to spherically swing the movable frame. The permanent magnet and the coil planarly extend parallel to tangent planes, tangent to imaginary spheres centered about the center, respectively. Any normal to the tangent plane of the permanent magnet is inclined to the optical axis of the front lens element such that a distance between the normal and the optical axis increases in a direction toward the object side.

Abstract: An imaging apparatus includes a front lens group having a front lens element and a reflector; a rear lens group, the imaging apparatus performing an image-stabilizing operation by driving the front lens element; a support member supporting the reflector; a support mechanism which supports the movable frame to spherically swing about a spherical-swinging center, positioned on an extension of the optical axis of the front lens element extending behind an underside of a reflection surface of the reflector; and a rotation preventer which prevents rotation of the movable frame about the optical axis of the front lens element while allowing the movable frame to spherically swing about the spherical-swinging center. The rotation preventer includes a projection and a projection insertion portion provided on the movable frame and the support member, respectively, or vice versa, and are engaged with each other.

Abstract: An imaging apparatus includes a front lens group, including a reflector element and a front lens element on the object side thereof, and a rear lens group; a support member, fixed to a fixed member that supports the reflector element, including a spherical-swinging operation support positioned behind the reflection surface of the reflector element and supporting a movable member supporting the front lens element to spherically swing about a predetermined point, a rotation preventer preventing the movable member from rotating about the optical axis of the front lens element, a detector supporter, and a mounting portion mounted to the fixed member; an actuator which drives the movable member to spherically swing the movable member in response to vibrations applied to the imaging optical system; a detector detecting positional variations of the movable member; and an adjuster which adjusts the position of the mounting portion relative to the fixed member.

Abstract: An excessively large electric current is suppressed from flowing to an electrode. Provision is made for an electrode arranged in an exhaust passage of an internal combustion engine, a power supply connected to the electrode for applying a voltage thereto, an air fuel ratio detection device for detecting or estimating an air fuel ratio of an exhaust gas which flows through the exhaust passage, and a power upper limit setting device for setting an upper limit for electric power supplied to the electrode from the power supply in cases where the air fuel ratio detected or estimate.