Akira Tsukamoto, Daisuke Suzuki, Koichi Yokosawa, Akihiko Kandori, Yusuke Seki, Kuniomi Ogata, Tsuyoshi Miyashita, Kazuo Saitoh, Keiji Tsukada
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引用次数: 1
Abstract
As a new clinical examination apparatus for cardiac diseases, attention is focused on the magnetocardiograph, which can represent electrophysiological phenomena of the heart noninvasively as graphical information. We have been developing a compact and portable high-temperature superconducting magnetocardiograph based on our technology for magnetocardiographs using low-temperature superconductors. Since a high-temperature superconducting magnetocardiograph can work with liquid nitrogen cooling, it allows miniaturization and lower running costs. Hence, it is expected to help popularize magnetocardiographs by its use in smaller hospitals and in group medical examinations in the field. In this paper, we introduce the prototype high-temperature superconducting magnetocardiographs we have made, and report the fabrication technology for a highly sensitive high-temperature SQUID and the technology for external noise shielding and compensation. © 2007 Wiley Periodicals, Inc. Electron Comm Jpn Pt 2, 90(4): 46– 55, 2007; Published online in Wiley InterScience (www.interscience.wiley.com). DOI 10.1002/ecjb.20273
高温超导磁心动图SQUID系统的研制
作为一种新型的心脏疾病临床检查仪器,心磁仪能够无创性地将心脏电生理现象以图形信息的形式表现出来,受到了广泛的关注。在低温超导体磁心仪技术的基础上,我们一直在开发一种紧凑型、便携式高温超导磁心仪。由于高温超导磁心仪可以在液氮冷却下工作,因此它可以小型化并降低运行成本。因此,它有望通过在小型医院和实地团体医疗检查中使用来帮助普及心脏磁图仪。本文介绍了我们研制的高温超导心磁仪样机,并报道了高灵敏度高温SQUID的制作工艺和外部噪声屏蔽与补偿技术。©2007 Wiley期刊公司电子工程学报,2009,29 (4):393 - 398;在线发表于Wiley InterScience (www.interscience.wiley.com)。DOI 10.1002 / ecjb.20273
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