Magari, JP
Katsuaki Magari, Kanagawa-Ken JP
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20090022903 | METHOD FOR MANUFACTURING A PERIODICALLY-POLED STRUCTURE - The present invention provides a periodically-poled structure with high conversion efficiency and improved manufacturing yield. The method for manufacturing a periodically-poled structure in a second order nonlinear optical crystal having a single domain structure ( | 01-22-2009 |
20090303486 | LIGHT SOURCE AND GAS MEASURING DEVICE - A light source is provided that realizes a single spectral linewidth having a half value width of 1 MHz or less and that is not influenced by the ambient temperature. A light source includes first laser ( | 12-10-2009 |
20100039699 | Wavelength Converter and Wavelength Conversion Apparatus - A wavelength converter which performs simultaneously wavelength conversion for a plurality of input light wavelengths that are unequally intervals, is provided. The nonlinear material of the wavelength converter has a modulation structure which has modulation of a nonlinear optical constant at a period Λ | 02-18-2010 |
20100053720 | LIGHT SOURCE APPARATUS WITH MODULATION FUNCTION AND ITS DRIVING METHOD - A light source apparatus with modulation function has a wavelength conversion module ( | 03-04-2010 |
Yoshifumi Magari, Itano-Gun JP
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20100203385 | NEGATIVE ELECTRODE FOR ALKALINE STORAGE BATTERY, FABRICATION METHOD THEREOF, AND ALKALINE STORAGE BATTERY - A negative electrode for alkaline storage battery using a hydrogen-absorbing alloy includes fluorinated oil and a surface active agent. | 08-12-2010 |
20100216018 | HYDROGEN-ABSORBING ALLOY AND ALKALINE STORAGE BATTERY HAVING THE ALLOY - A hydrogen-absorbing alloy is represented by the general formula Ln | 08-26-2010 |
Yoshifumi Magari, Kobe-Shi JP
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20110052983 | NEGATIVE ELECTRODE FOR ALKALINE STORAGE BATTERY AND ALKALINE STORAGE BATTERY - An alkaline storage battery having a positive electrode (1), a negative electrode (2), and an alkaline electrolyte solution, and the negative electrode having fluorinated oil being present on the surface thereof. The negative electrode includes a hydrogen-absorbing alloy represented by the general formula Ln | 03-03-2011 |
20110151320 | HYDROGEN-ABSORBING ALLOY, FABRICATION METHOD THEREOF AND ALKALINE STORAGE BATTERY - An alkaline storage battery has a negative electrode using a hydrogen-absorbing alloy represented by a general formula Ln | 06-23-2011 |
Yoshifumi Magari, Moriguchi-Shi JP
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20090061318 | Hydrogen-absorbing alloy and nickel-metal hydride storage battery - A hydrogen absorbing alloy is provided that is represented by the general formula Ln | 03-05-2009 |
Yoshifumi Magari, Osaka JP
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20090014100 | Method of making hydrogen-absorbing alloy for alkaline storage battery, and alkaline storage battery - A hydrogen-absorbing alloy for alkaline storage battery which is produced by a rapid cool using a rapid quenching method and whose component is represented by a general formula Ln | 01-15-2009 |
Yoshifumi Magari, Moriguchi City JP
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20090061317 | NEGATIVE ELECTRODE FOR ALKALINE STORAGE BATTERY AND ALKALINE STORAGE BATTERY - An alkaline storage battery has a positive electrode, a negative electrode utilizing hydrogen-absorbing alloy, and an alkaline electrolyte, and wherein the negative electrode contains a hydrogen-absorbing alloy represented by the general formula Ln | 03-05-2009 |
Yoshihide Magari, Takatsuki-Shi JP
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20130028388 | FLUOROSCOPIC X-RAY APPARATUS - When a multi-system setting command switch, targeted rotating position information switches, and a command executing switch are pressed down, a CPU reads out a path of frontal and lateral systems from a current position to a setting position from a setting position information memory, and reads out rotation direction and angle from a targeted position information memory. The CPU moves the frontal and lateral systems horizontally along the read-out path until the commanded setting position information conforms to detected actual position information. When the setting position information conforms to the actual position information, the frontal and lateral systems are rotated successively until the commanded rotation direction and angle conform to the detected actual position information. Thereby a fluoroscopic X-ray system can be moved smoothly from a standby position via the setting position to a targeted rotating position. | 01-31-2013 |