Your search keyword '"Kiyomi Takahashi"' showing total 11 results

1. Energy-discrimination x-ray computed tomography system utilizing a scanning cadmium-telluride detector

Author

Akira Ogawa, Manabu Watanabe, Jun Onagawa, Kiyomi Takahashi, Shigehiro Sato, Eiichi Sato, Keitaro Hitomi, Ablajan Abduraxit, and Toshiyuki Enomoto

Subjects

Physics, medicine.medical_specialty, Photon, business.industry, Amplifier, Detector, Photon energy, Cadmium telluride photovoltaics, Intensity (physics), Optics, medicine, Medical physics, Tomography, business, Energy (signal processing)

Abstract

An energy-discrimination K-edge x-ray computed tomography (CT) system is useful for controlling the image contrast of a target region by selecting both the photon energy and the energy width. The CT system has an oscillation-type linear cadmium telluride (CdTe) detectror. CT is performed by repeated linear scans and rotations of an object. Penetrating x-ray photons from the object are detected by a CdTe detector, and event signals of x-ray photons are produced using charge-sensitive and shaping amplifiers. Both photon energy and energy width are selected out using a multichannel analyzer, and the number of photons is counted by a counter card. In energy-discrimination CT, the tube voltage and tube current were 80 kV and 20 μA, respectively, and the x-ray intensity was 1.92 μGy/s at a distance of 1.0 m from the source and a tube voltage of 80 kV. The energy-discrimination CT was carried out by selecting x-ray photon energies.

Published

2010

2. Embossed radiography utilizing a subtraction program in conjunction with a 0.5-mm-focus x-ray tube

Author

Eiichi Sato, Manabu Watanabe, Kiyomi Takahashi, Purkhet Abderyim, Toshiyuki Enomoto, Jun Onagawa, Akira Ogawa, Hiroshi Matsukiyo, Shigehiro Sato, and Akihiro Osawa

Subjects

medicine.medical_specialty, Materials science, Pixel, business.industry, Radiography, Contrast resolution, Subtraction, X-ray tube, Flat panel detector, law.invention, Optics, law, medicine, Medical physics, Tube (container), business, Focus (optics)

Abstract

We developed an embossed radiography system utilizing single- and dual-energy subtractions for decreasing the absorption contrast of unnecessary regions, and contrast resolution of a target region was increased using image-shifting subtraction and a linear-contrast system in a flat panel detector (FPD). To carry out embossed radiography, we developed a computer program for two-dimensional subtraction, and a conventional x-ray generator with a 0.5-mm-focus tube was used. Energy subtraction was performed at tube voltages of 42.5 and 70.0 kV, a tube current of 1.0 mA, and an x-ray exposure time of 5.0 s. Embossed radiography was achieved with cohesion imaging by use of the FPD with pixel sizes of 48 ×48 μm, and the shifting dimension of an object in the horizontal and vertical directions ranged from 48 to 144 μm. We obtained high-contrast embossed images of fine bones and coronary arteries approximately 100 μm in diameter.

Published

2010

3. High-speed photon-counting x-ray computed tomography system utilizing a multipixel photon counter

Author

Keitaro Hitomi, Kiyomi Takahashi, Eiichi Sato, Toshiyuki Enomoto, Manabu Watanabe, Shigehiro Sato, Jun Onagawa, and Akiro Ogawa

Subjects

Physics, Photon, medicine.diagnostic_test, business.industry, Physics::Medical Physics, Detector, Scintillator, Photon energy, Photon counting, Particle detector, Optics, Personal computer, medicine, business, Medical radiography

Abstract

High-speed photon counting is useful for discriminating photon energy and for decreasing absorbed dose for patients in medical radiography, and the counting is usable for constructing an x-ray computed tomography (CT) system. A photon-counting x-ray CT system is of the first generation type and consists of an x-ray generator, a turn table, a translation stage, a two-stage controller, a multipixel photon counter (MPPC) module, a 1.0-mm-thick LSO crystal (scintillator), a counter card (CC), and a personal computer (PC). Tomography is accomplished by repeating the linear scanning and the rotation of an object, and projection curves of the object are obtained by the linear scanning using the detector consisting of a MPPC module and the LSO. The pulses of the event signal from the module are counted by the CC in conjunction with the PC. The lower level of the photon energy is roughly determined by a comparator circuit in the module, and the unit of the level is the photon equivalent (pe). Thus, the average photon energy of the x-ray spectra increases with increasing the lower-level voltage of the comparator. The maximum count rate was approximately 20 Mcps, and energy-discriminated CT was roughly carried out.

Published

2009

4. Tunable narrow-photon-energy x-ray source using a silicon single crystal

Author

Shigehiro Sato, Masanori Shozushima, Mitsuru Izumisawa, Akira Ogawa, Hidezo Mori, Toshiaki Kawai, Eiichi Sato, Toshio Ichimaru, Etsuro Tanaka, Takashi Inoue, Kiyomi Takahashi, and Kazuyoshi Takayama

Subjects

Physics, Silicon, business.industry, X-ray, chemistry.chemical_element, High voltage, Photon energy, Generator (circuit theory), Monocrystalline silicon, Crystal, Optics, chemistry, business, Single crystal

Abstract

A preliminary experiment for producing narrow-photon-energy cone-beam x-rays using a silicon single crystal is described. In order to produce low-photon-energy x-rays, a 100-µm-focus x-ray generator in conjunction with a (111) plane silicon crystal is employed. The x-ray beams from the source are confined by an x-y diaphragm, and monochromatic cone beams are formed by the crystal and three lead plates. The x-ray generator consists of a main controller and a unit with a high-voltage circuit and a 100-µm-focus x-ray tube. In this experiment, the maximum tube voltage and current were 35 kV and 0.50 mA, respectively, and the x-ray intensity of the microfocus generator was 343 μGy/s at 1.0 m from the source with a tube voltage of 30 kV and a current of 0.50 mA. The effective photon energy is determined by Bragg's angle, and the photon-energy width is regulated by the angle delta. Using this generator in conjunction with a computed radiography system, quasi-monochromatic radiography was performed using a cone beam with an effective energy of approximately 15.5 keV.

Published

2007

5. Novel monochromatic x-ray generators and their applications to high-speed radiography

Author

Takashi Inoue, Kazuyoshi Takayama, Etsuro Tanaka, Eiichi Sato, Kiyomi Takahashi, Hidezo Mori, Toshio Ichimaru, Mitsuru Izumisawa, Rudolf Germer, Haruo Obara, Shigehiro Sato, Akira Ogawa, and Toshiaki Kawai

Subjects

Physics, Generator (computer programming), business.industry, Radiography, X-ray, Image intensifier, Plasma, law.invention, Flash (photography), Optics, law, Harmonics, Monochromatic color, business

Abstract

Novel monochromatic x-ray generators and their applications to high-speed radiography are described. The five generators are as follows: a weakly ionized linear plasma x-ray generator, a monochromatic compact flash x-ray generator, a super-fluorescent plasma generator, a cerium x-ray generator using a 3.0-mm-thick aluminum filter, and a 100micron-focus x-ray generator utilizing the filter. Using the linear plasma generator with a copper target, we observed clean K lines and their harmonics, and soft flash radiography was performed with pulse widths of approximately 500 ns. The compact monochromatic flash x-ray generator produced clean molybdenum K lines easily, and high-speed radiography was performed with pulse widths of approximately 100 ns. Using a steady-state cerium x-ray generator, we performed real-time angiography utilizing an image intensifier and a high-sensitive camera (MLX) made by NAC Image Technology Inc. with a capture time of 1 ms. Finally, real-time magnification radiography was performed by twofold magnification imaging using a 100micron-focus x-ray generator and the high-sensitive camera.

Published

2007

6. Enhanced real-time magnification angiography utilizing a 100-μm-focus x-ray generator in conjunction with an image intensifier

Author

Shigehiro Sato, Hidezo Mori, Kazuyoshi Takayama, Eiichi Sato, Kiyomi Takahashi, Mitsuru Izumisawa, Toshiaki Kawai, Toshio Ichimaru, Akira Ogawa, Takashi Inoue, and Etsuro Tanaka

Subjects

Materials science, business.industry, Bremsstrahlung, Image intensifier, Magnification, High voltage, law.invention, Optics, law, Tube (fluid conveyance), X-ray generator, business, Digital radiography, Voltage

Abstract

A microfocus x-ray tube is useful in order to perform magnification digital radiography including phase-contrast effect. The 100-µm-focus x-ray generator consists of a main controller for regulating the tube voltage and current and a tube unit, with a high-voltage circuit and a fixed anode x-ray tube. The maximum tube voltage, current, and electric power were 105 kV, 0.5 mA, and 50 W, respectively. Using a 3.0-mm-thick aluminum filter, the x-ray intensity was 26.0 µGy/s at 1.0 m from the source with a tube voltage of 60 kV and a current of 0.50 mA. Because the peak photon energy was approximately 35 keV using the filter with a tube voltage of 60 kV, the bremsstrahlung x-rays were absorbed effectively by iodine-based contrast media with an iodine K-edge of 33.2 keV. Real-time magnification radiography was performed by twofold magnification imaging with an image intensifier camera, and angiography was achieved with iodine-based microspheres 15 µm in diameter. In angiography of non-living animals, we observed fine blood vessels of approximately 100 µm with high contrasts.

Published

2006

7. Super-characteristic x-ray generator utilizing a pipe and rod target

Author

Kiyomi Takahashi, Eiichi Sato, Toshio Ichimaru, Etsuro Tanaka, Takashi Inoue, Kazuyoshi Takayama, Hidezo Mori, Akira Ogawa, Toshiaki Kawai, Mitsuru Izumisawa, and Shigehiro Sato

Subjects

Materials science, business.industry, High voltage, Cathode, law.invention, Anode, Optics, law, Wehnelt cylinder, Electrode, Tube (fluid conveyance), Turbomolecular pump, business, Diode

Abstract

This generator consists of the following components: a constant high-voltage power supply, a filament power supply, a turbomolecular pump, and an x-ray tube. The x-ray tube is a demountable diode which is connected to the turbomolecular pump and consists of the following major devices: a tungsten hairpin cathode (filament), a focusing (Wehnelt) electrode, a polyethylene terephthalate x-ray window 0.25 mm in thickness, a stainless-steel tube body, a pipe target, and a rod target. The pipe and rod targets are useful for forming linear and cone beams, respectively. In the x-ray tube, the positive high voltage is applied to the anode (target) electrode, and the cathode is connected to the tube body (ground potential). In this experiment, the tube voltage applied was from12 to 20 kV, and the tube current was regulated to within 0.10 mA by the filament temperature. The exposure time is controlled in order to obtain optimum x-ray intensity. The electron beams from the cathode are converged to the target by the focusing electrode, and clean K-series characteristic x-rays are produced through the focusing electrode without using a filter. The x-ray intensities of the pipe and rod targets were 1.29 and 4.28 μGy/s at 1.0 m from the x-ray source with a tube voltage of 15 kV and a tube current of 0.10 mA, and quasi-monochromatic radiography was performed using a computed radiography system.

Published

2006

8. Extremely soft x-ray generator and its applications

Author

Eiichi Sato, Kazuyoshi Takayama, Hideaki Ido, Kiyomi Takahashi, Shigehiro Sato, Fumiko Obata, Etsuro Tanaka, Toshio Ichimaru, Hidezo Mori, and Toshiaki Kawai

Subjects

Materials science, business.industry, Radiography, Analytical chemistry, chemistry.chemical_element, Tungsten, law.invention, chemistry, law, Electrode, Optoelectronics, Beryllium, Computed radiography, business, Transformer, Voltage, Diode

Abstract

The development of an extremely soft x-ray generator with a tungsten-target tube and its applications to radiography and disinfection are described. This generator consists of a high-voltage power supply, a filament power supply, and an x-ray tube. Negative high voltages are applied to the cathode electrode in the x-ray tube, and the tube voltage and current are regulated by the input of a transformer and the filament voltage, respectively. The x-ray tube is a glass-enclosed double-focus diode with a tungsten target and a 0.2 mm-thick beryllium window. The maximum tube voltage and electric power were 60 kV and 400 W, respectively. The focal-spot sizes were 4×4 (large) and 1×1 mm (small), respectively. Extremely soft radiography was performed with a computed radiography system, and we observed fine blood vessels of about 100 μm with high contrasts. Using this generator, we performed the disinfection achieved with extremely soft x rays.

Published

2004

9. Weakly ionized cerium plasma radiography

Author

Kazuyoshi Takayama, Toshio Ichimaru, Etsuro Tanaka, Eiichi Sato, Hideaki Ido, Yasuomi Hayasi, Sigehiro Sato, Fumiko Obata, Toshiaki Kawai, Hidezo Mori, Kiyomi Takahashi, Kazunori Murakami, Yoshitake Koorikawa, and Rudolf Germer

Subjects

Analytical chemistry, chemistry.chemical_element, Plasma, Ion, law.invention, Cerium, chemistry, Triode, law, Electric field, Electrode, Atomic physics, Condenser (heat transfer), Voltage

Abstract

In the plasma flash x-ray generator, high-voltage main condenser of about 200 nF is charged up to 55 kV by a power supply, and electric charges in the condenser are discharged to an x-ray tube after triggering the cathode electrode. The flash x-rays are then produced. The x-ray tube is of a demountable triode that is connected to a turbo molecular pump with a pressure of approximately 1 mPa. As electron flows from the cathode electrode are roughly converged to a rod cerium target of 3.0 mm in diameter by electric field in the x-ray tube, the weakly ionized linear plasma, which consists of cerium ions and electrons, forms by target evaporating. At a charging voltage of 55 kV, the maximum tube voltage was almost equal to the charging voltage of the main condenser, and the peak current was about 20 kA. When the charging voltage was increased, weakly ionized cerium plasma formed, and the K-series characteristic x-ray intensities increased. The x-ray pulse widths were about 500 ns, and the time-integrated x-ray intensity had a value of about 40 μC/kg at 1.0 m from x-ray source with a charging voltage of 55 kV. In the angiography, we employed a film-less computed radiography (CR) system and iodine-based microspheres. Because K-series characteristic x-rays are absorbed easily by the microspheres, high-contrast angiography has been performed.

Published

2004

10. Quasi-monochromatic polycapillary imaging utilizing a computed radiography system

Author

Yasuomi Hayasi, Fumiko Obata, Etsuro Tanaka, Toshiaki Kawai, Toshio Ichimaru, Eiichi Sato, Hideaki Ido, Kiyomi Takahashi, Kazuyoshi Takayama, Sigehiro Sato, and Hidezo Mori

Subjects

Materials science, business.industry, Radiography, Hot cathode, Anode, law.invention, Optics, Characteristic X-ray, law, Electrode, Tube (fluid conveyance), Monochromatic color, Computed radiography, business

Abstract

A fundamental study on quasi-monochromatic parallel radiography using a polycapillary plate and a copper-target x-ray tube is described. The x-ray generator consists of a negative high-voltage power supply, a filament (hot cathode) power supply, and an x-ray tube. The negative high-voltage is applied to the cathode electrode, and the anode electrode is connected to the ground. In this experiment, the tube voltage was regulated from 12 to 22 kV, and the tube current was regulated within 3.0 mA by the filament temperature. The exposure time was controlled in order to obtain optimum x-ray intensity, and the maximum focal spot dimensions were approximately 2.0 x 1.5 mm. The polycapillary plate was J5022-16 (Hamamatsu Photonics Inc.), and the plate thickness was 1.0 mm. The outer, effective, and hole diameters were 33 mm, 27 mm, and 10 μm, respectively. Quasi-monochromatic x-rays were produced using a 10 μm-thick copper filter with a tube voltage of 17 kV, and these rays were formed into parallel beams by the polycapillary. The radiogram was taken using a computed radiography system utilizing imaging plates. In the measurement of image resolution, the resolution hadly varied according to increases in the distance between the chart and imaging plate using a polycapillary. We could observe a 50 μm tungsten wire clearly, and fine blood vessels of approximately 100 μm were visible in angiography.

Published

2004

11. Weakly ionized plasma flash x-ray generator and its distinctive characteristics

Author

Yasuomi Hayasi, Kazunori Murakami, Toshiaki Kawai, Etsuro Tanaka, Kazuyoshi Takayama, Toshio Ichimaru, Eiichi Sato, Yoshitake Koorikawa, Kiyomi Takahashi, Hidezo Mori, Sigehiro Sato, Rudolf Germer, Hideaki Ido, and Fumiko Obata

Subjects

Triode, Chemistry, law, Electric field, Electrode, Bremsstrahlung, Plasma, Atomic physics, X-ray generator, Condenser (heat transfer), Voltage, law.invention

Abstract

In the plasma flash x-ray generator, a high-voltage main condenser of approximately 200 nF is charged up to 50 kV by a power supply, and electric charges in the condenser are discharged to an x-ray tube after triggering the cathode electrode. The flash x-rays are then produced. The x-ray tube is a demountable triode that is connected to a turbo molecular pump with a pressure of approximately 1 mPa. As electron flows from the cathode electrode are roughly converged to a rod copper target of 3.0 mm in diameter by the electric field in the x-ray tube, weakly ionized linear plasma, which consists of copper ions and electrons, forms by target evaporation. At a charging voltage of 50 kV, the maximum tube voltage was almost equal to the charging voltage of the main condenser, and the peak current was about 15 kA. When the charging voltage was increased, the linear plasma formed, and the K-series characteristic x-ray intensities increased. The K-series lines were quite sharp and intense, and hardly any bremsstrahlung rays were detected. The x-ray pulse widths were approximately 700 ns, and the time-integrated x-ray intensity had a value of approximately 30 μC/kg at 1.0 m from the x-ray source with a charging voltage of 50 kV.

Published

2004