Differences between revisions 2 and 9 (spanning 7 versions)
Revision 2 as of 2008-07-10 08:47:34
Size: 662
Editor: RobertWard
Comment:
Revision 9 as of 2009-06-11 00:30:58
Size: 1753
Editor: RobertWard
Comment:
Deletions are marked like this. Additions are marked like this.
Line 5: Line 5:
Recently, our lock acquisition scheme is: The basic idea behind the process here (which differs from the approach of initial LIGO) is to first bring the interferometer under control (to 'lock' it) using signals which are naturally reasonably well diagonalized, and which have a large useful range. This initial lock point need not be at the operating point. The intial signals are:
Line 7: Line 7:
 *       TRX -> ETMX
 *       TRY -> ETMY
 *  REFL33_I -> PRC
 *  REFL33_Q -> MICH 
 * TRX -> ETMX
 * TRY -> ETMY
 * REFL33_I -> PRC
 * REFL33_Q -> MICH
Line 13: Line 13:
These signals bring us to a point where there is effectively a large CARM offset, which means that both ARM cavities are detuned from resonance by the same amount, in the same direction. This point is the ''acquistion point''.
Line 14: Line 15:
---------------------------- The remainder of the process of lock acquistion involves migration of signals and offsets, until the design configuration (the ''operating point'') is achieved. For a detuned RSE ifo, this operating point might be something like:
Line 16: Line 17:
 * DARM-> DC Readout
 * CARM -> REFL{1,2} I
 * PRCL -> REFL double demod
 * MICH -> AS double demod
 * SRCL -> PO double demod

The migrattory process which brings us from the acquistion point to the operating point is shown in the figure below. Some general notes on the procedure are in: [attachment:proc.pdf]


----------
Line 17: Line 28:
attachment:lock_control_sequence.png

Overview

To lock the detuned RSE configuration (sort of like LIGO-I + signal recycling), all of the interferometer's length degrees of freedom (DOF) are brought under control from an uncontrolled state. Typically this results in resonating the laser field within the resonant cavities formed by the interferomter optics and gives us a configuration which is optimal for audio-frequency gravitational-wave sensitivity.

The basic idea behind the process here (which differs from the approach of initial LIGO) is to first bring the interferometer under control (to 'lock' it) using signals which are naturally reasonably well diagonalized, and which have a large useful range. This initial lock point need not be at the operating point. The intial signals are:

  • TRX -> ETMX

  • TRY -> ETMY

  • REFL33_I -> PRC

  • REFL33_Q -> MICH

  • REFL166_I -> SRC

These signals bring us to a point where there is effectively a large CARM offset, which means that both ARM cavities are detuned from resonance by the same amount, in the same direction. This point is the acquistion point.

The remainder of the process of lock acquistion involves migration of signals and offsets, until the design configuration (the operating point) is achieved. For a detuned RSE ifo, this operating point might be something like:

  • DARM-> DC Readout

  • CARM -> REFL{1,2} I

  • PRCL -> REFL double demod

  • MICH -> AS double demod

  • SRCL -> PO double demod

The migrattory process which brings us from the acquistion point to the operating point is shown in the figure below. Some general notes on the procedure are in: [attachment:proc.pdf]


Detuned RSE lock acquisition procedure

attachment:lock_control_sequence.png

40m_Lock_Acquisition (last edited 2012-01-03 23:03:06 by localhost)