Title :
Active control of suspensions for a gravitational wave detector
Author :
Mehme, C. ; Caron, B. ; Marion, F. ; Mours, B. ; Flaminio, R.
Author_Institution :
LAMII, Annecy, France
Abstract :
This paper deals with large-scale gravitational-wave detector control. This detector is a laser illuminated large-scale interferometer which uses multiple optical elements and senses displacements as small as 10 -18m produced by gravitational waves. To make the detector operant, the variations of the cavities lengths must be sensed and corrected. The optical cavities are composed by mirrors suspended on vibration-isolated weighted pendulums which are used in order to attenuate the seismic noise due to the Earth motion. However the mirrors´ residual displacements once suspended to the damping system must be reduced by an order of 106 to make the detector operant. In this paper a linear quadratic Gaussian control law with loop transfer recovery (LQG/LTR) is designed in order to meet the requirements on seismic noise attenuation.
Keywords :
gravitational wave detectors; interference suppression; light interferometers; linear quadratic Gaussian control; mirrors; optical resonators; physical instrumentation control; position control; robust control; transfer function matrices; Earth motion; LQG/LTR; active control; displacements sensing; gravitational wave detector; linear quadratic Gaussian control law; loop transfer recovery; mirrors; optical cavities; optical elements; seismic noise; vibration-isolated weighted pendulums; Damping; Detectors; Earth; Large-scale systems; Mirrors; Optical attenuators; Optical interferometry; Optical noise; Optical sensors; Suspensions;
Conference_Titel :
Control Applications, 1997., Proceedings of the 1997 IEEE International Conference on
Conference_Location :
Hartford, CT, USA
Print_ISBN :
0-7803-3876-6
DOI :
10.1109/CCA.1997.627636
