Bilinear noise subtraction at the GEO 600 observatory

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • N. Mukund
  • J. Lough
  • C. Affeldt
  • F. Bergamin
  • A. Bisht
  • Marc Brinkmann
  • V. Kringel
  • H. Lück
  • S. Nadji
  • M. Weinert
  • K. Danzmann

Externe Organisationen

  • Max-Planck-Institut für Gravitationsphysik (Albert-Einstein-Institut)
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Details

OriginalspracheEnglisch
Aufsatznummer102006
Seitenumfang9
FachzeitschriftPhysical Review D
Jahrgang101
Ausgabenummer10
PublikationsstatusVeröffentlicht - 26 Mai 2020

Abstract

Longitudinal control signals used to keep gravitational wave detectors at a stable operating point are often affected by modulations from test mass misalignments leading to an elevated noise floor ranging from 50 to 500 Hz. Nonstationary noise of this kind results in modulation sidebands and increases the number of glitches observed in the calibrated strain data. These artifacts ultimately affect the data quality and decrease the efficiency of the data analysis pipelines looking for astrophysical signals from continuous waves as well as the transient events. In this work, we develop a scheme to subtract one such bilinear noise from the gravitational wave strain data and demonstrate it at the GEO 600 observatory. We estimate the coupling by making use of narrow-band signal injections that are already in place for noise projection purposes and construct a coherent bilinear signal by a two-stage system identification process. We improve upon the existing filter design techniques by employing a Bayesian adaptive directed search strategy that optimizes across the several key parameters that affect the accuracy of the estimated model. The scheme takes into account the possible nonstationarities in the coupling by periodically updating the involved filter coefficients. The resulting postoffline subtraction leads to a suppression of modulation sidebands around the calibration lines along with a broadband reduction of the midfrequency noise floor. The observed increase in the astrophysical range and a reduction in the occurrence of nonastrophysical transients suggest that the above method is a viable data cleaning technique for current and future generation gravitational wave observatories.

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Bilinear noise subtraction at the GEO 600 observatory. / Mukund, N.; Lough, J.; Affeldt, C. et al.
in: Physical Review D, Jahrgang 101, Nr. 10, 102006, 26.05.2020.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Mukund, N, Lough, J, Affeldt, C, Bergamin, F, Bisht, A, Brinkmann, M, Kringel, V, Lück, H, Nadji, S, Weinert, M & Danzmann, K 2020, 'Bilinear noise subtraction at the GEO 600 observatory', Physical Review D, Jg. 101, Nr. 10, 102006. https://doi.org/10.48550/arXiv.2001.00242, https://doi.org/10.1103/PhysRevD.101.102006
Mukund, N., Lough, J., Affeldt, C., Bergamin, F., Bisht, A., Brinkmann, M., Kringel, V., Lück, H., Nadji, S., Weinert, M., & Danzmann, K. (2020). Bilinear noise subtraction at the GEO 600 observatory. Physical Review D, 101(10), Artikel 102006. https://doi.org/10.48550/arXiv.2001.00242, https://doi.org/10.1103/PhysRevD.101.102006
Mukund N, Lough J, Affeldt C, Bergamin F, Bisht A, Brinkmann M et al. Bilinear noise subtraction at the GEO 600 observatory. Physical Review D. 2020 Mai 26;101(10):102006. doi: 10.48550/arXiv.2001.00242, 10.1103/PhysRevD.101.102006
Mukund, N. ; Lough, J. ; Affeldt, C. et al. / Bilinear noise subtraction at the GEO 600 observatory. in: Physical Review D. 2020 ; Jahrgang 101, Nr. 10.
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abstract = "Longitudinal control signals used to keep gravitational wave detectors at a stable operating point are often affected by modulations from test mass misalignments leading to an elevated noise floor ranging from 50 to 500 Hz. Nonstationary noise of this kind results in modulation sidebands and increases the number of glitches observed in the calibrated strain data. These artifacts ultimately affect the data quality and decrease the efficiency of the data analysis pipelines looking for astrophysical signals from continuous waves as well as the transient events. In this work, we develop a scheme to subtract one such bilinear noise from the gravitational wave strain data and demonstrate it at the GEO 600 observatory. We estimate the coupling by making use of narrow-band signal injections that are already in place for noise projection purposes and construct a coherent bilinear signal by a two-stage system identification process. We improve upon the existing filter design techniques by employing a Bayesian adaptive directed search strategy that optimizes across the several key parameters that affect the accuracy of the estimated model. The scheme takes into account the possible nonstationarities in the coupling by periodically updating the involved filter coefficients. The resulting postoffline subtraction leads to a suppression of modulation sidebands around the calibration lines along with a broadband reduction of the midfrequency noise floor. The observed increase in the astrophysical range and a reduction in the occurrence of nonastrophysical transients suggest that the above method is a viable data cleaning technique for current and future generation gravitational wave observatories.",
author = "N. Mukund and J. Lough and C. Affeldt and F. Bergamin and A. Bisht and Marc Brinkmann and V. Kringel and H. L{\"u}ck and S. Nadji and M. Weinert and K. Danzmann",
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T1 - Bilinear noise subtraction at the GEO 600 observatory

AU - Mukund, N.

AU - Lough, J.

AU - Affeldt, C.

AU - Bergamin, F.

AU - Bisht, A.

AU - Brinkmann, Marc

AU - Kringel, V.

AU - Lück, H.

AU - Nadji, S.

AU - Weinert, M.

AU - Danzmann, K.

N1 - Funding information: We thank the GEO collaboration for the construction of GEO 600, and Walter Graßfor his work in keeping the interferometer in a good running state. N. M. expresses thanks to Denis Martynov and Gautam Venugopalan for their valuable suggestions on the filtering scheme. Special thanks go to Sumit Kumar and Bhooshan Gadre for their insights on Bayesian parameter estimation. The authors are grateful for support from the Science and Technology Facilities Council (STFC) Grant No. ST/L000946/1, the University of Glasgow in the United Kingdom, the Bundesministerium für Bildung und Forschung (BMBF), and the State of Lower Saxony in Germany. This work was partly supported by the DFG grant SFB/Transregio 7 Gravitational Wave Astronomy. This document has been assigned LIGO document number LIGO-P1900350.

PY - 2020/5/26

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N2 - Longitudinal control signals used to keep gravitational wave detectors at a stable operating point are often affected by modulations from test mass misalignments leading to an elevated noise floor ranging from 50 to 500 Hz. Nonstationary noise of this kind results in modulation sidebands and increases the number of glitches observed in the calibrated strain data. These artifacts ultimately affect the data quality and decrease the efficiency of the data analysis pipelines looking for astrophysical signals from continuous waves as well as the transient events. In this work, we develop a scheme to subtract one such bilinear noise from the gravitational wave strain data and demonstrate it at the GEO 600 observatory. We estimate the coupling by making use of narrow-band signal injections that are already in place for noise projection purposes and construct a coherent bilinear signal by a two-stage system identification process. We improve upon the existing filter design techniques by employing a Bayesian adaptive directed search strategy that optimizes across the several key parameters that affect the accuracy of the estimated model. The scheme takes into account the possible nonstationarities in the coupling by periodically updating the involved filter coefficients. The resulting postoffline subtraction leads to a suppression of modulation sidebands around the calibration lines along with a broadband reduction of the midfrequency noise floor. The observed increase in the astrophysical range and a reduction in the occurrence of nonastrophysical transients suggest that the above method is a viable data cleaning technique for current and future generation gravitational wave observatories.

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