Optimized merging of search coil and fluxgate data for MMS

David Fischer; Werner Magnes; Christian Hagen; Ivan Dors; Mark W. Chutter; Jerry Needell; Roy B. Torbert; Olivier Le Contel; Robert J. Strangeway; Gernot Kubin; Aris Valavanoglou; Ferdinand Plaschke; Rumi Nakamura; Laurent Mirioni; Christopher T. Russell; Hannes K. Leinweber; Kenneth R. Bromund; Guan Le; Lawrence Kepko; Brian J. Anderson; James A. Slavin; Wolfgang Baumjohann

doi:10.5194/gi-5-521-2016

Optimized merging of search coil and fluxgate data for MMS

David Fischer
, Werner Magnes
, Christian Hagen
, Ivan Dors
, Mark W. Chutter
, Jerry Needell
, Roy B. Torbert
, Olivier Le Contel
, Robert J. Strangeway
, Gernot Kubin
, Aris Valavanoglou
, Ferdinand Plaschke
, Rumi Nakamura
, Laurent Mirioni
, Christopher T. Russell
, Hannes K. Leinweber
, Kenneth R. Bromund
, Guan Le
, Lawrence Kepko
, Brian J. Anderson

James A. Slavin, Wolfgang Baumjohann

Space Research Institute
Graz University of Technology
University of New Hampshire Durham
Institute of Geophysics and Planetary Physics, University of California
CNRS
NASA Goddard Space Flight Center
Johns Hopkins University Applied Physics Laboratory
University of Michigan, Ann Arbor

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

The Magnetospheric Multiscale mission (MMS) targets the characterization of fine-scale current structures in the Earth's tail and magnetopause. The high speed of these structures, when traversing one of the MMS spacecraft, creates magnetic field signatures that cross the sensitive frequency bands of both search coil and fluxgate magnetometers. Higher data quality for analysis of these events can be achieved by combining data from both instrument types and using the frequency bands with best sensitivity and signal-to-noise ratio from both sensors. This can be achieved by a model-based frequency compensation approach which requires the precise knowledge of instrument gain and phase properties. We discuss relevant aspects of the instrument design and the ground calibration activities, describe the model development and explain the application on in-flight data. Finally, we show the precision of this method by comparison of in-flight data. It confirms unity gain and a time difference of less than 100ĝ€μs between the different magnetometer instruments.

langue originale	Anglais
Pages (de - à)	521-530
Nombre de pages	10
journal	Geoscientific Instrumentation, Methods and Data Systems
Volume	5
Numéro de publication	2
Les DOIs	https://doi.org/10.5194/gi-5-521-2016
état	Publié - 17 nov. 2016

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Fischer, D., Magnes, W., Hagen, C., Dors, I., Chutter, M. W., Needell, J., Torbert, R. B., Le Contel, O., Strangeway, R. J., Kubin, G., Valavanoglou, A., Plaschke, F., Nakamura, R., Mirioni, L., Russell, C. T., Leinweber, H. K., Bromund, K. R., Le, G., Kepko, L., ... Baumjohann, W. (2016). Optimized merging of search coil and fluxgate data for MMS. Geoscientific Instrumentation, Methods and Data Systems, 5(2), 521-530. https://doi.org/10.5194/gi-5-521-2016

@article{36acb02f948e4ac288844fc3b4811d0b,

title = "Optimized merging of search coil and fluxgate data for MMS",

abstract = "The Magnetospheric Multiscale mission (MMS) targets the characterization of fine-scale current structures in the Earth's tail and magnetopause. The high speed of these structures, when traversing one of the MMS spacecraft, creates magnetic field signatures that cross the sensitive frequency bands of both search coil and fluxgate magnetometers. Higher data quality for analysis of these events can be achieved by combining data from both instrument types and using the frequency bands with best sensitivity and signal-to-noise ratio from both sensors. This can be achieved by a model-based frequency compensation approach which requires the precise knowledge of instrument gain and phase properties. We discuss relevant aspects of the instrument design and the ground calibration activities, describe the model development and explain the application on in-flight data. Finally, we show the precision of this method by comparison of in-flight data. It confirms unity gain and a time difference of less than 100ĝ€μs between the different magnetometer instruments.",

author = "David Fischer and Werner Magnes and Christian Hagen and Ivan Dors and Chutter, \{Mark W.\} and Jerry Needell and Torbert, \{Roy B.\} and \{Le Contel\}, Olivier and Strangeway, \{Robert J.\} and Gernot Kubin and Aris Valavanoglou and Ferdinand Plaschke and Rumi Nakamura and Laurent Mirioni and Russell, \{Christopher T.\} and Leinweber, \{Hannes K.\} and Bromund, \{Kenneth R.\} and Guan Le and Lawrence Kepko and Anderson, \{Brian J.\} and Slavin, \{James A.\} and Wolfgang Baumjohann",

note = "Publisher Copyright: {\textcopyright} Author(s) 2016.",

year = "2016",

month = nov,

day = "17",

doi = "10.5194/gi-5-521-2016",

language = "English",

volume = "5",

pages = "521--530",

journal = "Geoscientific Instrumentation, Methods and Data Systems",

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Fischer, D, Magnes, W, Hagen, C, Dors, I, Chutter, MW, Needell, J, Torbert, RB, Le Contel, O, Strangeway, RJ, Kubin, G, Valavanoglou, A, Plaschke, F, Nakamura, R, Mirioni, L, Russell, CT, Leinweber, HK, Bromund, KR, Le, G, Kepko, L, Anderson, BJ, Slavin, JA & Baumjohann, W 2016, 'Optimized merging of search coil and fluxgate data for MMS', Geoscientific Instrumentation, Methods and Data Systems, VOL. 5, Numéro 2, p. 521-530. https://doi.org/10.5194/gi-5-521-2016

TY - JOUR

T1 - Optimized merging of search coil and fluxgate data for MMS

AU - Fischer, David

AU - Magnes, Werner

AU - Hagen, Christian

AU - Dors, Ivan

AU - Chutter, Mark W.

AU - Needell, Jerry

AU - Torbert, Roy B.

AU - Le Contel, Olivier

AU - Strangeway, Robert J.

AU - Kubin, Gernot

AU - Valavanoglou, Aris

AU - Plaschke, Ferdinand

AU - Nakamura, Rumi

AU - Mirioni, Laurent

AU - Russell, Christopher T.

AU - Leinweber, Hannes K.

AU - Bromund, Kenneth R.

AU - Le, Guan

AU - Kepko, Lawrence

AU - Anderson, Brian J.

AU - Slavin, James A.

AU - Baumjohann, Wolfgang

PY - 2016/11/17

Y1 - 2016/11/17

N2 - The Magnetospheric Multiscale mission (MMS) targets the characterization of fine-scale current structures in the Earth's tail and magnetopause. The high speed of these structures, when traversing one of the MMS spacecraft, creates magnetic field signatures that cross the sensitive frequency bands of both search coil and fluxgate magnetometers. Higher data quality for analysis of these events can be achieved by combining data from both instrument types and using the frequency bands with best sensitivity and signal-to-noise ratio from both sensors. This can be achieved by a model-based frequency compensation approach which requires the precise knowledge of instrument gain and phase properties. We discuss relevant aspects of the instrument design and the ground calibration activities, describe the model development and explain the application on in-flight data. Finally, we show the precision of this method by comparison of in-flight data. It confirms unity gain and a time difference of less than 100ĝ€μs between the different magnetometer instruments.

AB - The Magnetospheric Multiscale mission (MMS) targets the characterization of fine-scale current structures in the Earth's tail and magnetopause. The high speed of these structures, when traversing one of the MMS spacecraft, creates magnetic field signatures that cross the sensitive frequency bands of both search coil and fluxgate magnetometers. Higher data quality for analysis of these events can be achieved by combining data from both instrument types and using the frequency bands with best sensitivity and signal-to-noise ratio from both sensors. This can be achieved by a model-based frequency compensation approach which requires the precise knowledge of instrument gain and phase properties. We discuss relevant aspects of the instrument design and the ground calibration activities, describe the model development and explain the application on in-flight data. Finally, we show the precision of this method by comparison of in-flight data. It confirms unity gain and a time difference of less than 100ĝ€μs between the different magnetometer instruments.

UR - https://www.scopus.com/pages/publications/84996963926

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DO - 10.5194/gi-5-521-2016

M3 - Article

AN - SCOPUS:84996963926

SN - 2193-0856

VL - 5

SP - 521

EP - 530

JO - Geoscientific Instrumentation, Methods and Data Systems

JF - Geoscientific Instrumentation, Methods and Data Systems

IS - 2

ER -

Optimized merging of search coil and fluxgate data for MMS

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