Inverted Pyramid 3-axis Silicon Hall Effect Magnetic Sensor With Offset Cancellation

arXiv - PHYS - Instrumentation and Detectors Pub Date : 2024-09-06 DOI:arxiv-2409.04333

Jacopo Ruggeri, Udo Ausserlechner, Helmut Köck, Karen M. Dowling

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Abstract

Microelectronic magnetic sensors are essential in diverse applications, including automotive, industrial, and consumer electronics. Hall-effect devices hold the largest share of the magnetic sensor market, and they are particularly valued for their reliability, low cost and CMOS compatibility. This paper introduces a novel 3-axis Hall-effect sensor element based on an inverted pyramid structure, realized by leveraging MEMS micromachining and CMOS processing. The devices are manufactured by etching the pyramid openings with TMAH and implanting the sloped walls with n-dopants to define the active area. Through the use of various bias-sense detection modes, the device is able to detect both in-plane and out-of-plane magnetic fields within a single compact structure. In addition, the offset can be significantly reduced by one to three orders of magnitude by employing the current-spinning method. The device presented in this work demonstrated high in-plane and out-of-plane current- and voltage-related sensitivities ranging between 64.1 to 198 V A$^{-1}$ T$^{-1}$ and 14.8 to 21.4 mV V$^{-1}$ T$^{-1}$, with crosstalk below 3.7 %. The sensor exhibits a thermal noise floor which corresponds to approximately 0.5 $\mu$T/$\sqrt{Hz}$ at 1.31 V supply. This novel Hall-effect sensor represents a promising and simpler alternative to existing state-of-the-art 3-axis magnetic sensors, offering a viable solution for precise and reliable magnetic field sensing in various applications such as position feedback and power monitoring.

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带偏移消除功能的倒金字塔三轴硅霍尔效应磁传感器

微电子磁传感器在汽车、工业和消费电子等各种应用中都至关重要。霍尔效应器件在磁传感器市场中占有最大份额，其可靠性、低成本和 CMOS 兼容性尤其受到重视。本文介绍了一种基于倒金字塔结构的新型三轴霍尔效应传感器元件，它是利用 MEMS 微机械加工和 CMOS 处理技术实现的。通过使用各种偏置感应检测模式，该器件能够在单一紧凑结构内检测平面内和平面外磁场。此外，通过采用电流旋转方法，偏移量可显著降低一到三个数量级。这项工作中展示的设备具有很高的平面内和平面外电流和电压相关灵敏度，分别为 64.1 到 198 V A$^{-1}$ T$^{-1}$ 和 14.8 到 21.4 mV V$^{-1}$ T$^{-1}$，串扰低于 3.7%。在 1.31 V 电源电压下，传感器的热噪声本底约为 0.5$\mu$T/$\sqrt{Hz}$。这种新型霍尔效应传感器是现有最先进的三轴磁场传感器的一种新型简易替代品，为位置反馈和功率监控等各种应用中精确可靠的磁场感应提供了可行的解决方案。

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arXiv - PHYS - Instrumentation and Detectors

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