[Yuta, Rana, Evan]
When Stefan left Friday evening, PRMI wouldn't lock. We poked around at MEDM screens for a while before deciding that a more systematic diagnosis was in order. We decided to attack just the Michelson first.
We parked PRM and misaligned ETMX. We then adjusted the LSC MICH filter bank to duplicate was was done for Kiwamu's and Yuta's previous Michelson lock characterization (elog 9698, 31 Jan 2014). Even with a 1:0 integrator engaged, we found that the Michelson would not lock for more than 30 s, and the error signal drifted by about a third of its peak-to-peak.
We were able to measure the OLTF, and found that it had a UGF of 3 Hz with no phase margin. Rana suggested we notch out the bounce mode of the BS suspension with filters from LLO. We got the filter, adjusted the frequency to the LHO BS (17.8 Hz, as measured from the REFLAIR_A_RF45_Q_ERR spectrum), and then added it to FM6 on LSC_MICH. After doing this, we found that the Michelson lock is much more stable --- it appears to lock indefinitely.
In order to calibrate REFLAIR_A_RF45_Q_ERR in terms of mirror motion, we let the Michelson swing freely and recorded the fringing. We know that the fringing amplitude (in counts) as a function of asymmetry l is A sin(4 pi l / lambda), so the linear portion has a slope of A * 4 pi / lambda, in counts per m. I took the swinging data, trended the minimum, median, and maximum, and then took the median of the trended minimum and maximum values. A histogram of these values is attached. From this I find A = 643 counts; this gives the conversion factor as 7.6 counts per nanometer.
We used this value to get a calibrated spectrum of the dark noise of REFLAIR_A_RF45_Q_ERR, which we measured with the modecleaner unlocked. A trended 10-minute time series is attached; we see that the drift is on the order of a few nanometers over this time period. Also attached is a spectrum of the dark noise, along with Yuta's estimate of the control signal (LSC_MICH_OUT) the Michelson, given in terms of length. The estimated length noise was 1.1 um RMS.
An OLTF of the improved Michelson loop is attached. The UGF is now 7.5 Hz, with a phase margin of 20 degrees. Also attached is Yuta's model of the expected OLTF; the agreeement is excellent around the UGF, except for the flat gain. This model uses already existing an already of the triple suspension of the BS (/ligo/svncommon/SusSVN/sus/trunk/Common/MatlabTools/TripleModel_Production).
We assumed that the suspension model gives BS actuation efficiency from H1:SUS-BS_M2_LOCK_L_OUTPUT to the actual M3 motion in m/counts. However, there is a missing factor of 1.7e-3 in this actuation efficiency to fit to the measured OLTF.
Written by Yuta
I found that I forgot to put 0.05 in my OLTF model (I forgot that the output matrix H1:LSC-OUTPUT_MTRX for MICH to BS was set to 0.05). I also forgot to put sqrt(2) to convert BS motion to MICH length change. I updated the OLTF figure, and now, the missing factor is 0.024.
Written by Yuta
The missing factor 0.024 was from the conversion factor in uN/counts.
I assumed that the suspension model I use gives me the transfer function in m/counts, but it was actually in m/uN.
The conversion factor can be calculated using the parameters in G1100968 (for BS specific, see T1100479);
0.963 N/A * 0.32 mA/V * 20.0/2**18 V/counts = 2.35e-8 N/counts = 0.024 uN/counts
The OLTF now agrees well with the expected. Thanks to Jeff K. and Arnaud!
(But still, there is a missing factor in the PD signal chain. The measured value 7.6 counts/nm is used in this expected curve. See alog #9630 and #9857)
Note that this factor(uN/counts) is also missing in the current noise budget model which lives in /ligo/svncommon/NbSVN/aligonoisebudget/trunk/PRMI.