A voice coil based electromagnetic system for calibration of a sub-micronewton torsional thrust stand

Jiang Kai Lam; Seong Chun Koay; Chie Haw Lim; Kean How Cheah

doi:10.1016/j.measurement.2018.09.029

A voice coil based electromagnetic system for calibration of a sub-micronewton torsional thrust stand

Jiang Kai Lam, Seong Chun Koay, Chie Haw Lim, Kean How Cheah

Research output: Journal Publication › Article › peer-review

20 Citations (Scopus)

Abstract

This paper presents the development of an alternative electromagnetic calibration system. Utilising commercially available voice coils and permanent magnets, the proposed system is able to generate linear, repeatable, and consistent steady-state calibration forces at over four orders of magnitude (30–23,000 µN). It is also capable of producing calibration impulse bits in the range of 12–668 µNs. The maximum uncertainty errors of the calibrator are evaluated as 18.48% and 11.38% for steady-state and impulsive forces calibration, respectively. Its performance is compared to other existing electromagnetic calibration techniques. Capability of the system is then demonstrated in calibrating a sub-micronewton torsional thrust stand.

Original language	English
Pages (from-to)	597-604
Number of pages	8
Journal	Measurement: Journal of the International Measurement Confederation
Volume	131
DOIs	https://doi.org/10.1016/j.measurement.2018.09.029
Publication status	Published - Jan 2019
Externally published	Yes

Keywords

Electromagnetic calibration
Micropropulsion
Sub-micronewton
Torsional thrust stand

ASJC Scopus subject areas

Instrumentation
Electrical and Electronic Engineering

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10.1016/j.measurement.2018.09.029

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title = "A voice coil based electromagnetic system for calibration of a sub-micronewton torsional thrust stand",

abstract = "This paper presents the development of an alternative electromagnetic calibration system. Utilising commercially available voice coils and permanent magnets, the proposed system is able to generate linear, repeatable, and consistent steady-state calibration forces at over four orders of magnitude (30–23,000 µN). It is also capable of producing calibration impulse bits in the range of 12–668 µNs. The maximum uncertainty errors of the calibrator are evaluated as 18.48% and 11.38% for steady-state and impulsive forces calibration, respectively. Its performance is compared to other existing electromagnetic calibration techniques. Capability of the system is then demonstrated in calibrating a sub-micronewton torsional thrust stand.",

keywords = "Electromagnetic calibration, Micropropulsion, Sub-micronewton, Torsional thrust stand",

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AU - Lam, Jiang Kai

AU - Koay, Seong Chun

AU - Lim, Chie Haw

AU - Cheah, Kean How

PY - 2019/1

Y1 - 2019/1

N2 - This paper presents the development of an alternative electromagnetic calibration system. Utilising commercially available voice coils and permanent magnets, the proposed system is able to generate linear, repeatable, and consistent steady-state calibration forces at over four orders of magnitude (30–23,000 µN). It is also capable of producing calibration impulse bits in the range of 12–668 µNs. The maximum uncertainty errors of the calibrator are evaluated as 18.48% and 11.38% for steady-state and impulsive forces calibration, respectively. Its performance is compared to other existing electromagnetic calibration techniques. Capability of the system is then demonstrated in calibrating a sub-micronewton torsional thrust stand.

AB - This paper presents the development of an alternative electromagnetic calibration system. Utilising commercially available voice coils and permanent magnets, the proposed system is able to generate linear, repeatable, and consistent steady-state calibration forces at over four orders of magnitude (30–23,000 µN). It is also capable of producing calibration impulse bits in the range of 12–668 µNs. The maximum uncertainty errors of the calibrator are evaluated as 18.48% and 11.38% for steady-state and impulsive forces calibration, respectively. Its performance is compared to other existing electromagnetic calibration techniques. Capability of the system is then demonstrated in calibrating a sub-micronewton torsional thrust stand.

KW - Electromagnetic calibration

KW - Micropropulsion

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JF - Measurement: Journal of the International Measurement Confederation

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A voice coil based electromagnetic system for calibration of a sub-micronewton torsional thrust stand

Abstract

Keywords

ASJC Scopus subject areas

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