A Gradiometric Magnetic Sensor System for Stray-Field-Immune Rotary Position Sensing in Harsh Environment

Huber, Samuel; Burssens, Jan-Willem; Dupré, Nicolas; Dubrulle, Olivier; Bidaux, Yves; Close, Gael F.; Schott, Christian

doi:10.3390/proceedings2130809

Cited by 10 publications

(7 citation statements)

References 5 publications

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Experimental Demonstration of Stray-Field Immunity beyond 5 mT for an Automotive-Grade Rotary Position Sensor

Dupré¹,

Dubrulle

Huber³

et al. 2018

Eurosensors 2018

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This paper experimentally demonstrates the stray-field robustness capability of a novel Hall-based rotary position sensor concept (Huber, S., et al, 2018). The sensor targets safety-related automotive applications, for example powertrain and power steering. In these applications, the safety requirement specifies a maximum stray-field induced error of 0.4°. Therefore, the robustness in corner cases needs to be assessed. We demonstrate the stray-field immunity in multiple corner cases for temperature from −40 °C up to 160 °C and over lifetime. The impact of a uniform 5 mT stray field over all conditions (3σ) is shown to be less than 0.25°. The fully-integrated automotive-qualified sensor is implemented in a 0.18-μm CMOS technology, and achieves 0.7° of angular accuracy.

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“…However, they require more space due to the overhead of the discrete coils. To address the stray-field challenge in Hall-based sensors, we developed a new gradiometric Hall sensor concept described in our companion paper [3].…”

Section: Introductionmentioning

confidence: 99%

Experimental Demonstration of Stray-Field Immunity beyond 5 mT for an Automotive-Grade Rotary Position Sensor

Dupré¹,

Dubrulle

Huber³

et al. 2018

Eurosensors 2018

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“…The development of MPO systems is an ongoing theoretical and experimental effort dealing mostly with stray field robustness [10], system fabrication tolerances and combining the signals of multiple sensors with sophisticated algorithms [7]. While such complex implementations can achieve a high level of precision and stability, they often neglect the production cost factor, which is a critical aspect for industrial applications.…”

Section: Problem and Motivationmentioning

confidence: 99%

Computationally Efficient Magnetic Position System Calibration

Lumetti

Malagò

Spitzer

et al. 2020

7th International Electronic Conference on Sensors and Applications

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Properties such as high resolution, contactless (and thus wear-free) measurement, low power consumption, robustness against temperature and contamination as well as low cost make magnetic position and orientation systems appealing for a large number of industrial applications. Nevertheless, one major practical challenge is their sensitivity to fabrication tolerances. In this work, we propose a novel method for magnetic position system calibration based on the analytical computation of the magnetic field and on the application of an evolutionary optimization algorithm. This scheme enables the calibration of more than 10 degrees of freedom within few seconds on standard quad-core ×86 processors and is demonstrated by calibrating a highly cost-efficient 3D-printed 3-axis magnetic joystick.

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“…In recent times, due to the increasing electrification of vehicles, stray-field immunity (SFI) has become a key requirement for automotive sensors [ 5 ]. A typical source of stray fields in hybrid or electric cars is the high-current wires, which can produce magnetic fields in the order of several millitesla [ 6 ].…”

Section: Introductionmentioning

confidence: 99%

Hybrid Magnetic–Inductive Angular Sensor with 360° Range and Stray-Field Immunity

Brajon¹,

Lugani²,

Close³

2022

Sensors

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Magnetic and inductive sensors are the dominant technologies in angular position sensing for automotive applications. This paper introduces a new angular sensor: a hybrid concept combining the magnetic Hall and inductive principles. A magnetic Hall transducer provides an accurate angle from 0° to 180°, whereas an inductive transducer provides a coarse angle from 0° to 360°. For this novel concept, a hybrid target with a magnetic and inductive signature is also needed. Using the two principles at the same time enables superior performances, in terms of range, compactness and robustness, that are not possible when used separately. We realized and characterized a prototype. The prototype achieves a 360° range, has a high accuracy and is robust against mechanical misalignments, stray fields and stray metals. The measurement results demonstrate that the two sensing principles are completely independent, thereby opening the doors for hybrid optimum magnetic–inductive designs beyond the usual trade-offs (range vs. resolution, size vs. robustness to misalignment).

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A Gradiometric Magnetic Sensor System for Stray-Field-Immune Rotary Position Sensing in Harsh Environment

Cited by 10 publications

References 5 publications

Experimental Demonstration of Stray-Field Immunity beyond 5 mT for an Automotive-Grade Rotary Position Sensor

Experimental Demonstration of Stray-Field Immunity beyond 5 mT for an Automotive-Grade Rotary Position Sensor

Computationally Efficient Magnetic Position System Calibration

Hybrid Magnetic–Inductive Angular Sensor with 360° Range and Stray-Field Immunity

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