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Optical Springs at the 40m 1 QND Workshop, Hannover Dec 14, 2005 Robert Ward for the 40m Team Osamu Miyakawa, Rana Adhikari, Matthew Evans, Benjamin Abbott,

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Presentation on theme: "Optical Springs at the 40m 1 QND Workshop, Hannover Dec 14, 2005 Robert Ward for the 40m Team Osamu Miyakawa, Rana Adhikari, Matthew Evans, Benjamin Abbott,"— Presentation transcript:

1 Optical Springs at the 40m 1 QND Workshop, Hannover Dec 14, 2005 Robert Ward for the 40m Team Osamu Miyakawa, Rana Adhikari, Matthew Evans, Benjamin Abbott, Rolf Bork, Daniel Busby, Hartmut Grote, Jay Heefner, Alexander Ivanov, Seiji Kawamura, Michael Smith, Robert Taylor, Monica Varvella, Stephen Vass, and Alan Weinstein

2 Optical Springs at the 40m 2 An interferometer as close as possible to the Advanced LIGO optical configuration and control system Caltech 40 meter prototype interferometer  Detuned Resonant Sideband Extraction (DRSE)  Power Recycling  Suspended mass  Single pendula  Digital controls system  Same cavity finesse as AdLIGO baseline design  100x shorter storage times.

3 Optical Springs at the 40m 3 AdLIGO signal extraction scheme  Arm cavity signals are extracted from beat between carrier and f 1 or f 2.  Central part (Michelson, PRC, SRC) signals are extracted from beat between f 1 and f 2, not including arm cavity information. f1f1 -f 1 f2f2 -f 2 Carrier (Resonant on arms) Single demodulation Arm information Double demodulation Central part information  Mach-Zehnder will be installed to eliminate sidebands of sidebands.  Only + f 2 is resonant on SRC.  Unbalanced sidebands of +/-f 2 due to detuned SRC produce good error signal for Central part. ETMy ETMx ITMy ITMx BS PRM SRM 4km f2f2 f1f1

4 Optical Springs at the 40m 4 The Story So Far To understand why we saw the optical springs in the way we have, it helps to know the story of Lock Acquisition at the 40m.

5 Optical Springs at the 40m 5 Transmitted light is used as 40m Lock Acquisition part I: Off-resonant lock scheme for a single cavity Off-resonant Lock point Resonant Lock

6 Optical Springs at the 40m 6 40m Lock acquisition procedure Start with no DOFs controlled, all optics aligned. ITMy ITMx BS PRM SRM SP DDM 13m MC 33MHz 166MHz SP33 SP166 AP DDM AP166 PO DDM

7 Optical Springs at the 40m 7 40m Lock acquisition procedure DRMI + 2arms with offset ITMy ITMx BS PRM SRM SP DDM 13m MC 33MHz 166MHz SP33 SP166 AP DDM AP166 PO DDM Average wait : 3 minute (at night, with tickler) T =7% I Q 1/sqrt(TrY) 1/sqrt(TrX)

8 Optical Springs at the 40m 8 40m Lock acquisition procedure ITMy ITMx BS PRM SRM SP DDM 13m MC 33MHz 166MHz SP33 SP166 AP DDM AP166 To DARM PO DDM AP166 / (TrX+TrY) CARM DARM + + Short DOFs -> DDM DARM -> RF signal CARM -> DC signal 1/sqrt(TrX)+ 1/sqrt( TrY) CARM -> Digital CM_MCL servo AlternativeAlternative path

9 Optical Springs at the 40m 9 40m Lock acquisition procedure Reduce CARM offset: 1. Go to higher ARM power 2. Switch on AC-coupled analog CM_AO servo, using REFL DC as error signal. 3. Switch to RF error signal (POX) at half-max power. 4. Reduce offset/increase gain of CM_AO. ITMy ITMx BS PRM SRM SP DDM 13m MC 33MHz 166MHz SP33 SP166 AP DDM AP166 To DARM REFL DARM PO DDM AP166 / (TrX+TrY) G PR =5 5. Packup MOPA and send it to LLO for S5

10 Optical Springs at the 40m 10 Optical spring in detuned RSE a :input vacuum b :output D : M : h :strain A. Buonanno, Y.Chen, Phys. Rev. D 64, 042006 (2001) h SQL :standard quantum limit t: transmissivity of SRM k: coupling constant F: GW sideband phase shift in SRC b: GW sideband phase shift in IFO z: homodyne phase Optical spring in detuned RSE was first predicted using two-photon formalism. a b D laser Signal recycling mirror h h

11 Optical Springs at the 40m 11 Detune Cartoon Carrier frequency frequency offset from carrier [Hz] Sideband amplitude [a.u.] FWHM USB LSB f sig Responses of GW USB and GW LSB are different due to the detuning of the signal recycling cavity. IFO Differential Arm mode is detuned from resonance at operating point SRCDARM IFO DARM/CARM slope related to spring constant? IFO Common Arm mode is detuned from resonance at intial locking point PRCCARM

12 Optical Springs at the 40m 12 DARM TFs as CARM offset is reduced

13 Optical Springs at the 40m 13 CARM optical springs Solid lines are from TCST Stars are 40m data Max Arm Power is ~80 Also saw CARM anti-springs, but don’t have that data

14 Optical Springs at the 40m 14 Optical spring and Optical resonance in differential arm mode of detuned RSE Optical gain of L- loop DARM_IN1/DARM_OUT divided by pendulum transfer function Optical spring and optical resonance of detuned RSE were measured. Frequency of optical spring depends on cavity power, mass, detuning phase of SRC. Frequency of optical resonance depends on detuning phase of SRC. Theoretical line was calculated using A. Buonanno and Y.Chen’s equations.

15 Optical Springs at the 40m 15 Positive spring constant SRM is locked at opposite position from anti-resonant carrier point(BRSE). Optical spring disappeared due to positive spring constant. Broadband RSE Broadband SR

16 Optical Springs at the 40m 16 Simple picture of optical spring in detuned RSE Let’s move arm differentially, X arm longer, Y arm shorter from full RSE  Power X arm down, Y arm up X arm down, Y arm down X arm up, Y arm down  Radiation pressure X arm down, Y arm up X arm down, Y arm down X arm up, Y arm down  Spring constant Negative(optical spring) N/A Positive(no optical spring) DARM (Lx-Ly) Power(W) BRSE Correct SRM position Wrong SRM position X arm Y arm

17 Optical Springs at the 40m 17 Relationship between the CARM and DARM springs at the 40m  With the 40m Lock Acquisition scheme, we only see a CARM spring if there’s also a DARM spring.  Details tomorrowtomorrow XarmYarmDARMCARM ++xx --0+ +-xx -++- Using the DC-locking scheme for the arms, there are, prima facie, four locking points corresponding to the four possible gain combinations, but only two will acquire lock. XarmYarmDARMCARM ++0- --xx +--+ -+xx Correct SRM position Incorrect SRM position

18 Optical Springs at the 40m 18 Will it lock? NO YES x-axis: EY position y-axis: signal blue:X err green: Y err black: DARM red: CARM modeled with FINESSE

19 Optical Springs at the 40m 19 Carrier 33MHz 166MHz ITMy ITMx BS PRM SRM OSA DDM PD DRMI lock using double demodulation with unbalanced RF sideband in SRC Carrier 33MHz Unbalanced 166MHz Belongs to next carrier Belongs to next carrier Belongs to next carrier OSA

20 Optical Springs at the 40m 20 Unbalanced Sideband Detection  Kentaro Somiya “ Photodetection method using unbalanced sidebands for squeezed quantum noise in a gravitational wave interferometer ” PHYSICAL REVIEW D 67,122001 2003  A. Buonanno, Y. Chen, N. Mavalvala, “Quantum noise in laser-interferometer gravitational-wave detectors with a heterodyne readout scheme” PHYSICAL REVIEW D 67,122005 2003  Can not be used to circumvent the standard quantum limit, due to heterodyne noise  Can be used to change the measurement quadrature, and thus reshape the GW response +166MHz sideband demodulation phase b1 b2

21 Optical Springs at the 40m 21 Changing the DARM quadrature Story: 1.Lock IFO with CARM offset 2.Handoff DARM to RF 3.Adjust RF demodulation phase 4.Reduce CARM offset 5.This changes the quadrature of the signal. As we are not compensating for this by adjusting the demod phase, the shape of the response changes. May also be some overall gain change due to imperfect normalization

22 Optical Springs at the 40m 22 Optickle Results GW response in a single, chosen quadrature at multiple CARM offsets

23 Optical Springs at the 40m 23 Why is the correct SRM position harder to lock?  The correctly detuned SRC doesn’t lock as easily as the oppositely tuned SRC  True for both full IFO and just the DRMI (though less noticeable on DRMI)  For full IFO, lock time goes from 1 to 5 minutes.  Have we just not tuned-it- up it right yet?

24 Optical Springs at the 40m 24 Mode healing/injuring at Dark Port Negative spring constant with optical spring Positive spring constant with no optical spring Repeatable The same alignment quality Carrier power at DP is 10x smaller

25 Optical Springs at the 40m 25 Compensating the resonances 4kHz >> UGF no compensation AdLIGO: 180 Hz ~ UGF 40Hz < UGF no compensation AdLIGO: 70Hz? 1kHz -> 100Hz ~ UGF dynamic compensationcompensation 0->100Hz ~ UGF not coherently compensated Compensation Filters for the various resonances: Optical Opto-mechanical DARM CARM UGFs ~ 250Hz

26 Optical Springs at the 40m 26 DARM loop: Calibration questions D C S P pendulum DARM Cavity response Sensing A Actuator F Feedback filter DARM_IN1 DARM_OUT DARM_IN2 EXC Use DARM_IN1 Measure DARM_IN2/EXC= Estimate S Measure (or estimate) C Use DARM_OUT Measure DARM_IN1/EXC= Estimate A Estimate P

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