Shielding factor enhancement method for Bi-stage active shield in SQUID-based Magnetocardiography system

2021 29th Iranian Conference on Electrical Engineering (ICEE) Pub Date : 2021-05-18 DOI:10.1109/ICEE52715.2021.9544217

Zeynab Alipour, F. Esmaeili, F. Shanehsazzadeh, M. Fardmanesh

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Abstract

We proposed a simple method to enhance shielding factor of our previously proposed bi-stage active shield system employed in a SQUID-based magnetocardiography system. The additional proposed design is optimized for canceling the power-line magnetic interference field to provide a calmer magnetic environment for the bi-stage active shield. A 50 Hz cancellation coil is placed around the bi-stage shielding system which includes inner and outer coils designed for compensating low-frequency (0-0.1Hz) and high-frequency (0.1-100Hz) environmental magnetic noise, respectively. In this configuration, a SQUID magnetometer is located at the center of these coils. Considering that the power-line interference is far-field, a coil-based sensor was placed on top of the liquid nitrogen Dewar which contains the SQUID magnetometer. The coil-based sensor is aligned with the SQUID sensing washer area vertically. Using optimized controlling circuits, the sensor measures the power-line magnetic interference field and feeds the measured signal to the 50 Hz cancellation coil. Although this configuration is optimized to reduce the power-line interferences, it also causes lower magnetic noise level at low-frequency range which is interpreted to be caused by decreasing flux trapping probability in the SQUID magnetometer. The designed 50Hz cancellation system has shielding factors of about 23 dB at 50Hz and 19 dB at 1Hz.

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基于squid的心脏磁图系统双级主动屏蔽屏蔽因子增强方法

我们提出了一种简单的方法来提高我们之前提出的双级有源屏蔽系统在基于squid的心脏磁图系统中的屏蔽系数。另外提出的设计针对消除电力线磁场干扰进行了优化，为双级有源屏蔽提供了更平静的磁环境。双级屏蔽系统包括用于补偿低频(0-0.1Hz)和高频(0.1-100Hz)环境磁噪声的内圈和外圈，周围放置了一个50 Hz的抵消线圈。在这种配置中，SQUID磁力计位于这些线圈的中心。考虑到电力线干扰是远场的，在包含SQUID磁力计的液氮杜瓦瓶顶部放置了一个基于线圈的传感器。基于线圈的传感器与SQUID传感垫圈垂直对齐。该传感器采用优化的控制电路，测量电力线的磁场干扰，并将测量到的信号馈送到50 Hz的抵消线圈。虽然这种配置是为了减少电力线干扰而优化的，但它也导致低频范围内的磁噪声水平降低，这被解释为是由于SQUID磁力计中的磁捕获概率降低造成的。所设计的50Hz抵消系统在50Hz时屏蔽系数约为23 dB，在1Hz时屏蔽系数约为19 dB。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 29th Iranian Conference on Electrical Engineering (ICEE)

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