Your search keyword '"NASU, Tatsuhiro"' showing total 3 results

1. Application of Dual Frequency Comb Method as an Approach to Improve the Performance of Multi-Frequency Simultaneous Radiation Doppler Radar for High Temperature Plasma Diagnostics

Author

TOKUZAWA, Tokihiko, INAGAKI, Shigeru, INOMOTO, Michiaki, EJIRI, Akira, NASU, Tatsuhiro, TSUJIMURA, Ii Toru, IDA, Katsumi, TOKUZAWA, Tokihiko, INAGAKI, Shigeru, INOMOTO, Michiaki, EJIRI, Akira, NASU, Tatsuhiro, TSUJIMURA, Ii Toru, and IDA, Katsumi

Abstract

A new Doppler radar using millimeter-waves in the Ka-band, named the “dual-comb Doppler reflectometer”, has been developed to measure the turbulence intensity and its velocity in high-temperature plasmas. For the realization of a fusion power generation, it is very important to know the spatial structure of turbulence, which is the cause of plasma confinement degradation. As a non-invasive and high spatial resolution measurement method for this purpose, we apply a multi-frequency Doppler radar especially with simultaneous multi-point measurement using a frequency comb. The newly developed method of synchronizing two frequency combs allows a lower intermediate frequency (IF) than the previously developed frequency comb radar, lowering the bandwidth of the data acquisition system and enabling low-cost, long-duration plasma measurements. In the current dual-comb radar system, IF bandwidth is less than 0.5 GHz; it used to be 8 GHz for the entire Ka-band probing. We applied this system to the high-temperature plasma experimental device, the Large Helical Device (LHD), and, to demonstrate this system, verified that it shows time variation similar to that of the existing Doppler radar measurements., source:Appl. Sci. 2022, 12(9), 4744; https://doi.org/10.3390/app12094744, source:https://doi.org/10.3390/app12094744, identifier:0000-0001-5473-2109

Published

2022

2. 3D metal powder additive manufacturing phased array antenna for multichannel Doppler reflectometer

Author

TOKUZAWA, Tokihiko, NASU, Tatsuhiro, INAGAKI, Shigeru, MOON, Chanho, IDO, Takeshi, IDEI, Hiroshi, EJIRI, Akira, IMAZAWA, Ryota, YOSHIDA, M., OYAMA, N., TANAKA, Kenji, IDA, Katsumi, TOKUZAWA, Tokihiko, NASU, Tatsuhiro, INAGAKI, Shigeru, MOON, Chanho, IDO, Takeshi, IDEI, Hiroshi, EJIRI, Akira, IMAZAWA, Ryota, YOSHIDA, M., OYAMA, N., TANAKA, Kenji, and IDA, Katsumi

Abstract

Measuring the time variation of the wavenumber spectrum of turbulence is important for understanding the characteristics of high-temperature plasmas, and the application of a Doppler reflectometer with simultaneous multi-frequency sources is expected. To implement this diagnostic in future fusion devices, the use of a phased array antenna (PAA) that can scan microwave beams without moving antennas is recommended. Since the frequency-scanning waveguide leaky-wave antenna-type PAA has a complex structure, we have investigated its characteristics by modeling it with 3D metal powder additive manufacturing (AM). First, a single waveguide is fabricated to understand the characteristics of 3D AM techniques, and it is clear that there are differences in performance depending on the direction of manufacture and surface treatment. Then, a PAA is made, and it is confirmed that the beam can be emitted in any direction by frequency scanning. The plasma flow velocity can be measured by applying the 3D manufacturing PAA to plasma measurement., source:Review of Scientific Instruments 93, 113535 (2022); https://doi.org/10.1063/5.0101723, source:https://doi.org/10.1063/5.0101723, identifier:0000-0001-5473-2109

Published

2022

3. Application of Dual Frequency Comb Method as an Approach to Improve the Performance of Multi-Frequency Simultaneous Radiation Doppler Radar for High Temperature Plasma Diagnostics

Author

Tokuzawa, Tokihiko, primary, Inagaki, Shigeru, additional, Inomoto, Michiaki, additional, Ejiri, Akira, additional, Nasu, Tatsuhiro, additional, Tsujimura, Toru Ii, additional, and Ida, Katsumi, additional

Published

2022