Improving the robustness of the advanced LIGO detectors to earthquakes

Authors

E. Schwartz, LIGO Livingston
A. Pele, LIGO Livingston
J. Warner, LIGO Hanford
B. Lantz, Stanford University
J. Betzwieser, LIGO Livingston
K. L. Dooley, University of Mississippi
S. Biscans, California Institute of Technology
M. Coughlin, University of Minnesota Twin Cities
N. Mukund, Max Planck Institute for Gravitational Physics (Albert Einstein Institute)
R. Abbott, California Institute of Technology
C. Adams, LIGO Livingston
R. X. Adhikari, California Institute of Technology
A. Ananyeva, California Institute of Technology
S. Appert, California Institute of Technology
K. Arai, California Institute of Technology
J. S. Areeda, California State University, Fullerton
Y. Asali, Columbia University
S. M. Aston, LIGO Livingston
C. Austin, Louisiana State University
A. M. Baer, Christopher Newport University
M. Ball, University of Oregon
S. W. Ballmer, Syracuse University
S. Banagiri, University of Minnesota Twin Cities
D. Barker, LIGO Hanford
L. Barsotti, LIGO, Massachusetts Institute of Technology
J. Bartlett, LIGO Hanford
B. K. Berger, Stanford University
D. Bhattacharjee, Missouri University of Science and Technology
G. Billingsley, California Institute of Technology
C. D. Blair, LIGO Livingston
R. M. Blair, LIGO Hanford
N. Bode, Max Planck Institute for Gravitational Physics (Albert Einstein Institute)
P. Booker, Max Planck Institute for Gravitational Physics (Albert Einstein Institute)

Document Type

Article

Publication Date

12-1-2020

Abstract

Teleseismic, or distant, earthquakes regularly disrupt the operation of ground-based gravitational wave detectors such as Advanced LIGO. Here, we present EQ mode, a new global control scheme, consisting of an automated sequence of optimized control filters that reduces and coordinates the motion of the seismic isolation platforms during earthquakes. This, in turn, suppresses the differential motion of the interferometer arms with respect to one another, resulting in a reduction of DARM signal at frequencies below 100 mHz. Our method greatly improved the interferometers' capability to remain operational during earthquakes, with ground velocities up to 3.9 μm s-1 rms in the beam direction, setting a new record for both detectors. This sets a milestone in seismic controls of the Advanced LIGO detectors' ability to manage high ground motion induced by earthquakes, opening a path for further robust operation in other extreme environmental conditions.

Publication Source (Journal or Book title)

Classical and Quantum Gravity

Recommended Citation

Schwartz, E., Pele, A., Warner, J., Lantz, B., Betzwieser, J., Dooley, K., Biscans, S., Coughlin, M., Mukund, N., Abbott, R., Adams, C., Adhikari, R., Ananyeva, A., Appert, S., Arai, K., Areeda, J., Asali, Y., Aston, S., Austin, C., Baer, A., Ball, M., Ballmer, S., Banagiri, S., Barker, D., Barsotti, L., Bartlett, J., Berger, B., Bhattacharjee, D., Billingsley, G., Blair, C., Blair, R., Bode, N., & Booker, P. (2020). Improving the robustness of the advanced LIGO detectors to earthquakes. Classical and Quantum Gravity, 37 (23) https://doi.org/10.1088/1361-6382/abbc8c