Low-noise permalloy ring cores for fluxgate magnetometers

Miles, David M.; Ciurzynski, M.; Barona, David; Narod, B. Barry; Bennest, J. R.; Kale, A.; Lessard, M.; Milling, D. K.; Larson, Joshua H.; Mann, I. R.

doi:10.5194/gi-8-227-2019

Cited by 28 publications

(19 citation statements)

References 40 publications

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“…Many parallel fluxgate magnetometers have been developed so far, as introduced in 1), 2), and 3). Recently, Miles et al 14) developed low-noise permalloy ring cores for parallel fluxgate magnetometers which achieved noise level of 6 to 11 pT/Hz 1/2 . There is a possibility to reduce the noise level of those sensors using the DC-biased excitation method.…”

Section: Discussionmentioning

confidence: 99%

Noise Suppression in Parallel Fluxgate Magnetometers by DC-Biased Excitation Method

et al. 2020

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We experimentally revealed that a direct current (DC) biased excitation method can reduce the noise in parallel fluxgate magnetometers composed of a permalloy ring core. The noise suppression was achieved by decreasing the Barkhausen noise and increasing the open-loop sensitivity using the nonlinearity of the B-H curve with the DC-biased excitation. The noise performance depends on the excitation parameters: frequency, amplitude, and DC-bias. We proposed that the parameters should be determined based on the evaluation of the sensitivity and noise level in both open-loop and closed-loop modes. Specifically, a contour map of the closed-loop noise is useful for understanding the noise decrease with different values of the amplitude and DC-bias. We also demonstrated the effectiveness of the DC-biased excitation method using a commercially available fluxgate magnetometer (APS520A, Applied Physics Systems). Using the DC-biased excitation method, the noise level was approximately one-fourth compared to that of the original electronics.

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Section: Discussionmentioning

confidence: 99%

Noise Suppression in Parallel Fluxgate Magnetometers by DC-Biased Excitation Method

et al. 2020

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“…In this scenario, which is summarized in Table 3, many of the spacecraft support systems would be based on components developed at the Space Sciences Laboratory at the University of California, Berkeley (UCB/SSL) for the Cubesat Radio Interferometry Experiment (CURIE) mission (Sundkvist et al, 2016), which is slated to launch and operate in late 2021. Likewise, the probe magnetometers would be based on instruments and technology (e.g., Miles et al, 2019) developed at the University of Iowa (UIowa).…”

Section: Probe Spacecraftmentioning

confidence: 99%

“…This system, based on the MGF instrument (Wallis et al, 2015) on Cassiope/ e-POP, also draws heritage from the fluxgate magnetometer (Miles et al, 2016) for the Ex-Alta 1 CubeSat (Mann et al, 2020) in the QB50 constellation (Wicks and Miles, 2019). The next-generation, nanosatellite-scale "Tesseract" magnetometer sensor (Figure 7A) leverages low-noise custom fluxgate cores (Miles et al, 2019) to create a compact, rigid, symmetric, and magnetically stable probe. This sensor design also incorporates temperature compensation (Miles et al, 2017), which may be advantageous for some potential trajectories (e.g., lunar orbit; Section 4.2).…”

Section: Magnetometermentioning

confidence: 99%

MagneToRE: Mapping the 3-D Magnetic Structure of the Solar Wind Using a Large Constellation of Nanosatellites

Maruca

Rueda

Bandyopadhyay

et al. 2021

Front. Astron. Space Sci.

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Unlike the vast majority of astrophysical plasmas, the solar wind is accessible to spacecraft, which for decades have carried in-situ instruments for directly measuring its particles and fields. Though such measurements provide precise and detailed information, a single spacecraft on its own cannot disentangle spatial and temporal fluctuations. Even a modest constellation of in-situ spacecraft, though capable of characterizing fluctuations at one or more scales, cannot fully determine the plasma’s 3-D structure. We describe here a concept for a new mission, the Magnetic Topology Reconstruction Explorer (MagneToRE), that would comprise a large constellation of in-situ spacecraft and would, for the first time, enable 3-D maps to be reconstructed of the solar wind’s dynamic magnetic structure. Each of these nanosatellites would be based on the CubeSat form-factor and carry a compact fluxgate magnetometer. A larger spacecraft would deploy these smaller ones and also serve as their telemetry link to the ground and as a host for ancillary scientific instruments. Such an ambitious mission would be feasible under typical funding constraints thanks to advances in the miniaturization of spacecraft and instruments and breakthroughs in data science and machine learning.

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“…Hz [62][63][64] and even down to 100 fT/ √ Hz with the device based on epitaxial yttrium iron garnet films having a specially graded edge profile [65]. The detection signal frequency is in the low-frequency range (from 1 Hz to 100 Hz) which is suitable for the measurement of magnetocardiography, magnetoencephalography, and magnetomyography signals.…”

mentioning

confidence: 99%

Ultrasensitive Magnetic Field Sensors for Biomedical Applications

Murzin

Mapps

Levada

et al. 2020

Sensors

140

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The development of magnetic field sensors for biomedical applications primarily focuses on equivalent magnetic noise reduction or overall design improvement in order to make them smaller and cheaper while keeping the required values of a limit of detection. One of the cutting-edge topics today is the use of magnetic field sensors for applications such as magnetocardiography, magnetotomography, magnetomyography, magnetoneurography, or their application in point-of-care devices. This introductory review focuses on modern magnetic field sensors suitable for biomedicine applications from a physical point of view and provides an overview of recent studies in this field. Types of magnetic field sensors include direct current superconducting quantum interference devices, search coil, fluxgate, magnetoelectric, giant magneto-impedance, anisotropic/giant/tunneling magnetoresistance, optically pumped, cavity optomechanical, Hall effect, magnetoelastic, spin wave interferometry, and those based on the behavior of nitrogen-vacancy centers in the atomic lattice of diamond.

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Low-noise permalloy ring cores for fluxgate magnetometers

Cited by 28 publications

References 40 publications

Noise Suppression in Parallel Fluxgate Magnetometers by DC-Biased Excitation Method

Noise Suppression in Parallel Fluxgate Magnetometers by DC-Biased Excitation Method

MagneToRE: Mapping the 3-D Magnetic Structure of the Solar Wind Using a Large Constellation of Nanosatellites

Ultrasensitive Magnetic Field Sensors for Biomedical Applications

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