Shoshana, Michael, Jim

Today we went into the PSL and started putting together the 2 complete CRS assemblies we have cleaned and ready to go. This went pretty smoothly and we now have to mostly done CRS, sans HOQI readout. We don't have flexures we can use, so we can't suspend or do any mechanical tuning, but proof masses are installed in the frames, mass adjustment hardware and picos are mounted. Tomorrow, we will probably look at what prep we can do on the other 2 CRS, but fasteners are still working through c&b for those, so I don't know there is much to do until those come out.

Ibrahim, Betsy, Randy

Today, we:

• Took the BBSS out of the can after securing the BSFM.
• Prepped the BBSS
  • blew the suspension with nitrogen top gun from top down
  • took the lifting plates out and set it down on its assembly tooling
  • attached the 45 degree lifting arms
• Prepped the ERGO arm
  • 2 adjustment O-rings had to be re-installed
  • BBS plate was used to lift practice glass
  • Dry run of where it would go with the optic was done
• Prepped the Aluma-Lift
  • cleaned the lift arms
  • positioned and dry-ran the path it would take during install 

Particle counts were checked periodically and were under 75 consistently during acitvity

See pictures.

TITLE: 05/13 Day Shift: 1430-2330 UTC (0730-1630 PST), all times posted in UTC
STATE of H1: Planned Engineering
INCOMING OPERATOR: None
SHIFT SUMMARY:

ISS PD Array and BBSS work continues.  Had a couple of big school field trip visits.

Odd weather day with fairly high winds and rain for most of the day.
LOG:

• 1534-1717 technical cleaning (optics lab and then LVEA + set-up at the old H2 PSL enclosure for upcoming work to be done inside it) [kim]
• 1545-1805 SQZT7 taking panels off (sheila)
  • 1556-1657 tony joining
• 1554-1746 BBSS work working on connecting the Bigger Beamspliter to the suspension frame in the coming days (ibrahim)
  • 1601- betsy joining
  • 1643 oli joining
  • 1700 randy joining
• 1611- 1613 Opening PSL Light pipe for ISS pd array & returning to control room to look at alignment (keita)
• 1627-1634 HAM6 ramp down rga bakeout & then move to CP1 to begin leak checking (jordan)
• 1708- ~2000 CRS (Cyllindrical Rotation Sensor) work at h2psl (jim,michaelR,shoshana)
• 1713-1935 ISS PD Array (keita,rahul)
• 1732-1815 EX ground studies continue (robert)
• 1736-1850 technical cleaning @EX (kim)
• 1751 SUSR2 rackwork for SPI (josh)
• 1800-1918 BBSS team returns for test stand to continue move to install the Bbs (betsy.randy.ibrahim)
• ~1730-1838 TCS plumbing work (tj,madi)
• 1830-1845 Outlook Elementary School tour (Amber)
• 1915-1930 Outlook Elementary School tour (Cassidy)
• 2018- 2149 TCS plumbing work cont.; will leave the chiller ON overnight. (tj,madi)
• 2039-2252 BBSS team returns to Test Stand (ibrahim, betsy, randy)
  • 2216 randy out
• 2042 HAM6 RGA (jordan)
• 2046-2230 SPI build + possible laser hazard in the optics lab (Jeff)
• 2049 CRS work at h2psl (jim,michaelR,shoshana)
• 2049-2155 electronics work for CRS near h2psl (richard,fil)
• 2055-2116 Escorted rebar inspector to CEBEX site & made lunch (corey)
• 2100 ISS PD Array alignment cont (keita.rahul)
  • 2229 Elenna joining for picomotor help
  • 2329 Rahul out
• 2206 restarting bake of RGA at HAM6 and another quick check at 2330 (jordan)
• 2238-2255 Closing TCSy table (was letting it dry out) [tj]

Ibrahim, Betsy, Oli

BBS01 AOSEM flag standoffs were removed, concluding gluing.

BBS01 was flipped to the HR Side via the inspection fixture.

Betsy and I then first contacted the HR Side (S1) and peeled an hour or so later.

We did not see any features or defects as we did with S2.

Camilla C, Madi S., TJ S

Just as we did with the TCSX table a few weeks ago (alog90078), we swapped all of the flex lines on the table. Most of this was done last week, but today Madi and I fisnished the last two lines today. We then used the same vacuum trick to suck water into the table lines to "test" the lines over lunch, and then plugged the table back into the full system and slowly turned on the chiller. We had one leak at the laser driver, but cutting and reseating the 1/8"OD tube seemed to fix it. 

While trying to removed the old 3/4"OD return tube from the tee, I managed to bump the iris next to the bottom periscope mirror. We'll have to recheck this when we have beam again and can some HWS tests.

The chiller is running, I'll check on things in the morning.

H1 ISI CPS Sensor Noise Spectra Check - Weekly FAMIS 39336

For some context, most of the Corner station is vented and the BS cartridge is not in the chamber which explains what is shown on the BS plots here..

J Freed, M Pirello,

We continued the progress to install the SPI RF chain as well as measured the 80MHz RF power along key points along the chain. 

SPI_RACK_LAYOUT_SUS-R2.png Shows the schematic of the rack layout for SPI in HAM 3 as well as measured power along that chain. We currently have the entire chain installed to just before the 2W amp. The main thing of note is that we have more power than even our most optimistic estimate. (We were expecting about 5dBm, MAX 8dBm, but we have 9.5dBm). The Heliax cables are much more efficient than we expected. As such next on the list is to install attenuators such that we get the power we expect. 

IMG_0627.jpg Shows the current Balun/Spitter set up. There is not really a good place to put the splitter on the SUS-R2 rack as the Patch Panel "walls" prevent using zip-ties or velcro to attach the Splitter on the sides of the SUS-R2 rack. Above the patch panel is the top of the rack; and below cables are in the way. As such, the least intrusive way is to attach the splitter to the balun (The transformer that converts the balanced Heliax cable to the unbalanced coax N-type cable), and add some strain relief on it. Not sure how effective this strain relief is but its better than nothing.

Marc also set up the 18V and 24V DC that powers the Double Mixer and other chassis that will eventually be installed. 

Next steps: 

1. Add attenuators such that the power going into the 2W amp would be correct.

2. Do phase noise measurements on the output power of the Double Mixer and see if anything has changed since 90179 

3. Test if instead of Attenuators we can attenuate the power output of the double mixer by adjusting the input voltage of the 4096Hz signal from the CDS that goes to the Double Mixer

J. Kissel 

SPI Wiring Diagram: D2400111-v6
In-chamber in-vac cable routing: In-vac Cable Routing Plan from G2401479-v3

I never aLOGged our choice of cable-table bracket floor assignment down when we originally assembled and signal-checked the D2400107-v4, so during disassembly in prep for upgrade to D2400107-v5 (LHO:90225) I took the time to write down the cable routing, cable serial number assignment, and cable table bracket (CBT) floor assignment:

Path       PD Name         PD SN          Duopus      D9 CBT Name / Floor     Quadrapus    D25 CBT Name / Floor 
                      |----------D2600001--------|  
                      D1600083 Type 2     D2400341    D2000492                D2400343     D2000492 
    
                                                                              S2500512
IFO REF    A/B        S2401096/S2401095   S2500516    CBT 2 / 2nd of 2        cable E      CBT 1 / 1st of 2   
IFO MEAS   A/B        S2401097/S2401098   S2500514    CBT 2 / 1st of 2        cable D      CBT 1 / 1st of 2
FBR PWR    REF/MEAS   S2401094/S2401093   S2500515    CBT 3 / 2nd of 2        cable C      CBT 1 / 1st of 2

                           PD SN          Monopus 
                      |----------D2600002--------|
                      D1600083 Type 3     D2400340

OL ISIK    QPD B      S2401091            S2500518    CBT 3 / 1st of 2        cable B      CBT 1 / 1st of 2

First and Second of the attached pictures are of the CBT 2 cable routing. I needed two pictures because the D9 end's two-part backshell of IFO REF cable was assembled with its serial number stamped on one side of one part, and the other side of the other part. C'est la vie.

Third picture is of CBT 3's cable routing.

The 2x D9 CBT assemblies (since the "type" we've assembled is not explicitly drawn in D2000492) are 
    - QTY 1x D2000519 baseplate
    - QTY 1x D2000520 "Type 2" two-floor uprights, with
    - QTY 2x D2200443 D9 adapters,
    - QTY 2x 1/4"-20 x 0.625" L captive SHCS (95966A512) for securing to the HAM table (rather than the 3/8"-16 captive SHCS that are used to secure to the BSC tables)
    - QTY 2x #6-32 x 0.375"L SHCS (92200A146) for securing the baseplate to the upright
    - QTY 2x per D9 adapter (4x total) #4-40 x 0.224"L ("2D"; 1185-04EN224) nitronic 60 helicoils for each of the upright holes
    - QTY 2x per D9 adapter (4x total) #4-40 x 0.5"L captive SHCS (95966A140) for securing the adapters to the upright

For the single D25 2-floor CBT that holds the D25 ends of the PD and picomotor quadrapuses, we used the standard D2000492 Type 2 configuration.

Restored the alignment sliders for IM2 and IM3 back to Monday values ([IM2P, Y] =[765, -187.7], [IM3P, Y]=[-560.7, 320]).

Measured the flashes. Chose the flash that gave the MC2 trans sum maximum power, which in general agreed with IM4 trans sum max but didn't with ISS QPD nor array PD inner sum nor outer sum. 

Anyway, 

• MC2 trans: SUM=21; seg1=0.0027; seg2=0.0029; seg3=0.0024; seg4=0.0022
  • i.e. PIT=0.098, YAW=-0.039
• IM4 trans: SUM=0.0276; seg1=0.00876; seg2= 0.00760; seg3=0.00456; seg4=0.00526
  • i.e. PIT=0.25, YAW=0.07
• ISS QPD: SUM 362; seg1=67; seg2=13; seg3=13; seg4=271
  • i.e. PIT= -0.56, YAW=0.86
• ISS Inner: SUM 0.023
• ISS Outer: SUM 0.104

PIT and YAW numbers were after normalization divided by (seg1+2+3+4), not by SUM, so there's a small difference but that doesn't matter at this point.

IM4 TRANS and ISS QPD PIT and YAW are broadly in agreement with Jenne's alog 90206 i.e.

• IM4 Trans Pit 0.2 Yaw 0.05 (Monday)
• ISS QPD Pit -0.53 YAW 0.85 (Monday)

I haven't compared the ISS Outer SUM with March 2026 when IMC was locked with 2W. Somebody check please. We'll go into chamber and start checking the beam path.

J. Kissel
E2600106 / IIET:37433
D2400107-v4

I've decommissioned the SPI pathfinder's ISIK Transceiver as it stands now (D2400107-v4) by 
    - disconnecting all electronics cabling; PDs at the cable-table bracket and picomotors' quadrupus at each pico-actuated optic
    - disconnecting optic fibers
    - untangling the in-vac cabling and fibers, ensuring the
    - installing installation handles (LHO:90223)
    - setting up a new set of 1"D x 6"L class-B posts then
    - removed the 3x temporary class-B bolts and washers that had secured the breadboard to the posts
    - lifting and transferring the D2400107-v4 assembly over to the other position and
    - securing there with the 3x temporary class B bolts.

Pictures of the move attached.

J. Kissel
ISIK Transceiver Assembly D2400107-v5
ISIK Installation Handle Assembly D2500215-v2

In prep for moving the old version of the SPI pathfinder's ISIK transceiver (D2400107-v4) with CVM100 mounts to the side, I assembled and fit-checked the (Class-B) ISIK Installation Handle Assembly D2500215. It fit! The only detail that required clock cycles was understanding which hardware went to which hole, so I made some redlines and posted them to D2500215-v2.

Attached are pictures before moving ye ol' 'board.

Nice work ANU!

TITLE: 05/13 Day Shift: 1430-2330 UTC (0730-1630 PST), all times posted in UTC
STATE of H1: Planned Engineering
OUTGOING OPERATOR: None
CURRENT ENVIRONMENT:
    SEI_ENV state: MAINTENANCE
    Wind: 19mph Gusts, 13mph 3min avg
    Primary useism: 0.04 μm/s
    Secondary useism: 0.10 μm/s 
QUICK SUMMARY:

ISS PD Array + LVEA Laser Hazard will continue.  BBSS work continues at the Test Stand.

Rainy & windy morning (just had quick wind storm with gusts reaching almost 50mph just passed...forecast is for a windy day).

We started with yesterday's alignment. I checked flashes in ISS array PDs and didn't like that the balances between them were very much different from how they were when IMC was locked back in March.

Then we started changing IM2 and IM3 to see if we can get back, but I was appalled that the flashes became stronger and stronger on array PDs as we aligned, which probably means that the beam was almost falling off of the PDs when we started. 

That shouldn't have stopped us because we don't know where the beam was on the array PDs when MC was locked (people gave up optimizing that path because things didn't make sense), it could have been falling off of the diode (because each diode is 2mm,  QPD is 3mm, the beam size is ~250um or so, and the beam was almost in one quadrant of the QPD). But I started thinking about many what-ifs and wasted time.

After all, since IM4 TRANS and ISS array QPD are both reasonably close to March 2026 position, we know that the beam position as well as angle of the beam injected into ISS path from IM4 are already close to those when IMC was good in vacuum.

What we should do is this:

• Revert back to Monday IM2/IM3 alignment. Confirm that the IM4 trans position as well as ISS array QPD position are OK.
• Check flashes in 2nd loop inloop and out-of-loop sum. Recheck if at least one of them is comparable to when IMC was locked back in March, taking into account the power difference, even though Sheila checked it yesterday. At this point, we'll have established again that the position and the angle of the beam coming into the ISS path are reasonable.
• Check that the beam in ISS path is nowhere near being clipped by baffles and ISS array cover and the elevator aperture of the ISS array. Don't fix clipping right away, do it after swapping the array because we'll have to move pico mirrors anyway.
• Swap the array. There's no assurance that the beam will be on the QPD right away but that's OK. We can move the unit on the spacer if that helps. Go as close as you can, then start using the two pico steering mirrors. Use the array input aperture to aid the process.
• Once you see the beam on the QPD, continue to center the QPD, fix clipping, not necessarily in this order.
• Check the flash height of array PDs as well as QPD, see if things makes sense.

Other things to note:

This is not required for the alignment but it's helpful to know how much we can move the beam on QPD. In an unlikely event where we somehow lose the beam in vacuum on the array QPD after IMC is locked, we might be able to scan IM3/IM2 to regain the beam on QPD, and slowly move IM3/IM2 back to the nominal position while pico-ing so the beam isn't lost on the QPD. If the beam is not clipped, the beam displacement on the QPD is ~3mm per 1mrad of IM3 rotation using parameters collected from various documents, see attached script.

The same script shows you that the Gouy phase separation between two pico mirrors is 10 degrees (if we use the beam parameter in Matt Heintze's alog 12537, which was probably obtained by the measurement of the bypassed beam) or about 20 degrees (if we use IMC eigenmode parameter propagated to the ISS path using D1200693).

Another thing is, if we believe the design eigenmode number rather than the measured bypassed beam in Matt's alog, the beam waist will be smaller and at about 20cm upstream of the PDs. The beam size on the PDs is about twice as large as it should be (470um rather than 250um). I cannot measure the beamsize of the flashes so we won't do anything, but that's something to remember. If IM3 has enough actuation range, we can later lock the IMC, scan the beam across the PD until the beam falls off, see how sharp the fall-off is, and use the diameter of the PD (3mm) to determine the size of the beam. Maybe a good project for a fellow.

Shoshana, MichaelR, Jim 

This morning we started moving parts into the lvea to start doing CRS assembly in the H2 PSL enclosure. We should have parts for 2 complete sensors right now (minus HOQIs), and should be getting the remaining parts out of clean and bake soon. We spent a lot of time trying to debug the H2 fans and hvac, but it seems not everything is fully functional yet. HEPA units are running in the anteroom however, which should be enough for us to keep parts clean while we assemble. I put a dust monitor in on a table and took counts, they stayed the in 50-100 range while I was watching. Parts are set on one of the stainless shelving units, we can use the stainless table in the anteroom for assembly for now. 

I had a look at some of the data from Leo Schrader's SURF project, in particular the measured overlaps of the sqz beam with the OMC posted 86485 and the measured q parameters on SQZT7 posted in 86365.  

I first took the measured q parameters, and using finesse propagated them to the OMC and calculated overlaps, which are plotted as sqrt(vertical overlap * horizontal overlap).  The attached scatter plot shows the predicted overlaps compared to the measured overlaps as the ZM4 + ZM5 strain guage voltages vary.  You can see that for the nominal O4 settings of -0.4V ZM5, 6.2V ZM4, the measured q agrees pretty well with the measured overlap.  Moving away from the nominal values, some of the measured qs do not seem very compatible with nearby measured overlaps.  (note, these measurements cover the whole PZT range of 0-200V for both psams, the strain gauges just have different ranges.)

I then tried to use the overlap data to take a gues at what this means for the actuation range of ZM4 + ZM5 psams.  I used the following information from Camille to estimate the ROC of ZM4 and ZM5.  

• ZM4 is SN1, characterization data in E2100289 indicates that before the preloading was changed in chamber, with 0V on the PZT the optical power was -106mD.  In 75677 the pre-load was increased by 29 in lbs, T2300426 says the preload should increase the optical power by 2.4 mD/ in lb of preloading, so after preloading the optical power with 0 V on the PZT should have been -36mD, or an ROC of -55.5 meters.  0V on the PZT now corresponds to 2V on the strain guage.  
• ZM5 is SN4, E2100291 says with 0V on the PZT the optical power was 667mD with 20 in lbs of preload.  75709 says the preload was increased to 47 in lbs, so 27 in lbs of preload was added.  I assumed that the optical power change with pre-load is the same for ZM4 as ZM5, and estimate that the optical power after the pre-load change the optical power with 0V on the PZT should be 729 mD, or an ROC of 2.737 meters.  0V on the PZT now corresponds to -5.2V.  

I used these estimates for optical power with 0V on the PZT and varied a linear slope of optical power per strain guage voltage.  Assuming a slope of mD/V for each psams, I estimated the ROCs of each mirror.  For any set of psams slopes, I estimated the q before ZM4 by using the measured q for the nominal strain guage values of 6.2 and -0.4V. I flipped the sign of the real part and propagated it back to before reflection off ZM4 using the estimated ROCs for that slope, then flipped the sign of the real part again to reverse propagation direction. (Thanks Keita and Disha for help understanding how to flip the qs).  I then propagated that estimated q back through the ZMs allowing the strain gauge voltage to vary and calculated overlap with the OMC.  This approach garantees that the nominal strain gage of 6.2V -0.4V the contour will match the 2.3% mismatch estimated from the measured q there. It would be nice to do an actual fit, and also allow the ROCs at 0V on the PZTs to vary, to see if we can get a better match to the dataset that way.  

In the example contour plot I've put ZM4 at -10mD/V strain gage, which means -0.36mD/V PZT, and the O4 nominal ROC would be -25.6meters.  ZM5 is at -13mD/V strain gage, which means -.47 mD/V pzt and nominal ROC of 2.99 during O4.  

Lastly, I made a plot of propagation of the measured qs to the output of the AR side of SRM, that we can compare to Evan Hall's much nicer plots of SEC and arm cavity modes at SRM.  

The script used to make these plots can be found in the commissoning-modeling-repo here.

(Jordan V., Dave B., Gerardo M.)

The internal pressure to CP1 turned around overnight signaling that the process of emptying the trap is complete, now we'll continue to monitor and pump on the cryotrap volume.until good pressure is achieved.

A side note, I manually turned off the CC for PT114B last night at 9:44 pm (local time) as the pressure was rising a bit high, then turned it back on this morning at 5:33 am local time.

Attached is a snapshot of one day trend data of pressure behavior regarding the soft regeneration for CP1.

Process started here.

J. Kissel, J. Warner
ECR: E2400026
WPs: 13237, LHO:13238
Final Design Doc: T2400145
Relevant Systems Level Drawings:
    . Mechanical Assemblies
        :: ISIJ Reflector D2400102
        :: HAM Table Baffles D1700335
        :: HAM2 Systems Layout D0901083 (not yet-inclusive-of-SPI)
    . Electronics Wiring Diagram 
    . Cable Routing In-vac Cable Routing Plan from G2401479 (pages )
    . Flange Layout D1002873-v11

Executive summary:
    - Removed ISIJ +X-side, center, HAM2 ISI table baffle from D1700265-v4 Type 2 
        :: Bracket mounting bolts left screwed into ISI optical table for this will eventually become a D1700265-v4 Type 3 and remounted.
    - Installed ISIJ Reflector + QPD Assembly D2400102 on +X ISI side wall (D071057-v2), with its shroud (D2500030) in place
        :: We didn't weigh it, but the SW Assembly predicts a mass of 1.96 [kg], which we can likely round up to 2.0 [kg] with the shroud installed.
    - Routed and connected QPD read-out cable system to D3 flange, F10 spigot.
    - Routed and connected picomotor cable system to existing D1101515 quadrupus leg Cable #3, J4 
        :: Cable #4, J5 is connected to IO PM5 mirror, Cables #2 J3 and #1 J2 were reset in neat coil with connectors floating to avoid electrical grounding as before.
    - Nudged make-shift baffle system using D1700261 ballast mass baffle mounted vertically on the +X / +Y / Beam Height corner of the chamber wall upon entry into beamtube.
        :: the will DEFINITELY need a technically-minded reset.

In at 10:30a PT and out by 12:30a PT. It's so lovely when everything goes to plan!

Pictures and further info to follow in the comments below.