Seismic isolation and suspension systems for advanced LIGO

Authors

N. A. Robertson, Ginzton Laboratory
B. Abbott, California Institute of Technology
R. Abbott, LIGO Livingston
R. Adhikari, LIGO, Massachusetts Institute of Technology
G. Allen, Ginzton Laboratory
H. Armandula, California Institute of Technology
S. Aston, University of Birmingham
A. Baglino, Ginzton Laboratory
M. Barton, California Institute of Technology
B. Bland, LIGO Hanford
R. Bork, California Institute of Technology
J. Bogenstahl, University of Glasgow
G. Cagnoli, University of Glasgow
C. Campbell, Ginzton Laboratory
C. A. Cantley, University of Glasgow
K. Carter, LIGO Livingston
D. Cook, LIGO Hanford
D. Coyne, California Institute of Technology
D. Crooks, University of Glasgow
E. Daw, Louisiana State University
D. DeBra, Stanford University
E. Elliffe, University of Glasgow
J. Faludi, Ginzton Laboratory
P. Fritschel, LIGO, Massachusetts Institute of Technology
A. Ganguli, Ginzton Laboratory
J. Giaime, LIGO Livingston
S. Gossler, Gottfried Wilhelm Leibniz Universität Hannover
A. Grant, University of Glasgow
J. Greenhalgh, Rutherford Appleton Laboratory
M. Hammond, LIGO Livingston
J. Hanson, LIGO Livingston
C. Hardham, Ginzton Laboratory
G. Harry, LIGO, Massachusetts Institute of Technology

Document Type

Conference Proceeding

Publication Date

12-1-2004

Abstract

To meet the overall isolation and alignment requirements for the optics in Advanced LIGO, the planned upgrade to LIGO, the US laser interferometric gravitational wave observatory, we are developing three sub-systems: a hydraulic external pre-isolator for low frequency alignment and control, a two-stage active isolation platform designed to give a factor of ∼1000 attenuation at 10 Hz, and a multiple pendulum suspension system that provides passive isolation above a few hertz. The hydraulic stage uses laminar-flow quiet hydraulic actuators with millimeter range, and provides isolation and alignment for the optics payload below 10 Hz, including correction for measured Earth tides and the microseism. This stage supports the in-vacuum two-stage active isolation platform, which reduces vibration using force feedback from inertial sensor signals in six degrees of freedom. The platform provides a quiet, controlled structure to mount the suspension system. This latter system has been developed from the triple pendulum suspension used in GEO 600, the German/UK gravitational wave detector. To meet the more stringent noise levels required in Advanced LIGO, the baseline design for the most sensitive optics calls for a quadruple pendulum, whose final stage consists of a 40 kg sapphire mirror suspended on fused silica ribbons to reduce suspension thermal noise.

Publication Source (Journal or Book title)

Proceedings of SPIE - The International Society for Optical Engineering

First Page

81

Last Page

91

Recommended Citation

Robertson, N., Abbott, B., Abbott, R., Adhikari, R., Allen, G., Armandula, H., Aston, S., Baglino, A., Barton, M., Bland, B., Bork, R., Bogenstahl, J., Cagnoli, G., Campbell, C., Cantley, C., Carter, K., Cook, D., Coyne, D., Crooks, D., Daw, E., DeBra, D., Elliffe, E., Faludi, J., Fritschel, P., Ganguli, A., Giaime, J., Gossler, S., Grant, A., Greenhalgh, J., Hammond, M., Hanson, J., Hardham, C., & Harry, G. (2004). Seismic isolation and suspension systems for advanced LIGO. Proceedings of SPIE - The International Society for Optical Engineering, 5500, 81-91. https://doi.org/10.1117/12.552469