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Koji Arai – LIGO Laboratory / Caltech LIGO-G1401386-v1.

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Presentation on theme: "Koji Arai – LIGO Laboratory / Caltech LIGO-G1401386-v1."— Presentation transcript:

1 Koji Arai – LIGO Laboratory / Caltech LIGO-G1401386-v1

2  Interferometer control using the main laser beam  On the top of the local control, optical path lengths and the mirror alignment need to be kept at the most sensitive state of the interferometer

3  Pound-Drever-Hall (PDH) technique  We want to keep the cavity at the TOP of the resonance  Phase of the cavity reflection is linear to the cavity detuning  Use modulation / demodulation Drever, R. W. P., et al Appl Phys B 31 97-105 (1983) http://en.wikipedia.org/wiki/Pound%E2%80%93Drever%E2%80%93Hall_technique http://www.sjsu.edu/faculty/beyersdorf/Archive/Phys208F07/Sideband%20generation%20in%20LIGO.pdf Detuning PDH Error signal Cavity Ref Power Cavity Ref Phase

4  Phasor diagram

5  Modulation sidebands  Phase modulationAmplitude modulation

6  Phasor diagram vs Sideband picture  2nd order? 3rd order? sidebands rotate at the rate of m total field shows phase modulation at m

7  Time dependent electric field vs Sideband picture They are equivalent!

8  Note: Photodetectors don’t feel phase modulation!

9  Two quadratures of PM  Two quadratures of AM  Relationship between PM and FM (freq modulaition)

10  RF x LO & LPF  Two demodulation quadratures (I&Q)

11  Use the interferometer as PM-AM converter

12  Sideband picture  Carrier experiences “fast phase change” depending on the length of the interferometer

13  Phasor picture  Reflected field on Resonance Detuned total field only has phase modulation at m total field has amplitude modulation at m carrier phase shift No power modulation Power modulation at m => Photocurrent demodulated at m shows the linear signal to the detuning!

14  Michelson is operated at the dark fringe for the shot noise and the power recycling  At the dark fringe, DC signals can’t be a good error signal  Schnupp asymmetry: Introduce small arm length asymmetry => RF sidebands leaks to the dark port

15  Schnupp asymmetry ~ sideband picture  Because of the asymmetry, the dark port is no longer dark for the sidebands even if the carrier is at dark.

16  Schnupp asymmetry ~ phasor picture

17  Actual aLIGO Length control scheme

18  For signal extraction purpose we need to resonate two sidebands (f1 and f2).  f1 +1/-1 SBs should be resonant in the PRC  f2 +1/-1 SBs should be resonant in both the PRC and SRC  The carrier, f1 SBs, and f2 SBs needs to go through the resonances of the input mode cleaner. (f1 = n fFSR_MC, f2 = m fFSR_MC)

19

20  Transition from non-operational state to the final linear state  Nonlinear process ~ Lock Acquisition  Before the lock, we can’t make a diagnosis of the control loops Without diagnosis, the lock is difficult. (Chicken & egg problem) iLIGO Lock acquisition PRMI locked Yarm locked Xarm locked

21  Mirror velocity vs Required actuator force  Mirror momentum:p = m v  Interaction time:dt = w / v  Required force: F dt = m v => F = m v^2 / w  For single arm case:  m: 40kg, v: 1um/s, w: 1nm => 0.04N  For common mode (double cavity) case:  m: 40kg, v: 1um/s, w: 0.03nm => 1.3N  For DC control of a 1m pendulum for 1um displacement  F = m g / l x = 0.4 mN  3000 times smaller!  We want longer interaction time! (quieter mirror)

22  Probabilistic lock & Deterministic lock  Arm Length Stabilization (aka green locking)  Transmission locking  3f locking  PDH linearization

23 K. Izumi er al, ”Multicolor cavity metrology”, J. Opt. Soc. Am. A 29 (2012) 2092-2103

24 Green Locking for one arm (40m prototype)

25 Transmission locking Off-resonant Lock point Resonant Lock R. Ward PhD thesis (2009) California Institute of Technology https://dcc.ligo.org/LIGO-P1400105

26 3f locking (aka Arai technique!) K. Arai PhD thesis (2001) Univ. of Tokyo http://t-munu.phys.s.u-tokyo.ac.jp/theses/arai_d.pdf

27

28

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30 PDH linearization M. Evans PhD thesis (2002) California Institute of Tech http://www.ligo.caltech.edu/~mevans/lockAcq/thesis.pdf

31 not needed

32 Find arm resonances Offset arms Lock DRMI Transition from ALS to IR signals Reduce CARM offset Transition DRMI 3f to 1f Engage CM/AO Transition to reflection RF signal (REFL9I) Align recycling mirrors >95% coupled into IFO

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