Attached here are the data files of acoustic transfer functions computed during O3. The computation follows LIGO document  LIGO-G1800121-v1 by P.Nguyen and R.Schofield. Also attached is one matlab script that demonstrates the reading of TF files and the projection computation for one assigned gps.

• WE building, injections performed August 19 2019, elog 46708: TF file, TF plot and projection plot
• NE building, injections performed October 6 2019, elog 47122: TF file, TF plot and projection plot
• CEB building, injections performed  April 26 2019, elog 45471: TF file, TF plot and projection plot
• CEB building, injections performed  March 26 2020, elog 48816: TF file, TF plot and projection plot
• CEB building with SQZ shutter closed, injections performed March 28 2020, elog 48846: TF file, TF plot and projection plot
• Detection LAB, injections performed on March 28 2020: TF file, TF plot and projection plot (using SQZ microphone as witness sensor)
• Detection LAB with SQZ shutter closed, injections performed on March  28 2020: TF file, TF plot and projection plot (using SQZ microphone as witness sensor)

The full set of data is stored in /data/procdata/detchar/env/injections/acoustic/results/O3/.

The acoustic noise coupling and projections reported in this entry are wrong, because of a bug in the software (my fault). They will be reposted shortly.

In order to reduce the data flow stored in the RAW_FULL stream and in the RAW stream, the following processes were stopped and made as optional in the VPM configuration file:

2020-04-08-04h39m19-UTC    info masserot     process:EnvDemod stopped

2020-04-08-04h46m15-UTC    info masserot     process:EOM_Demod stopped
2020-04-08-04h46m43-UTC    info masserot     process:LNFS_Moni stopped

2020-04-08-07h45m57-UTC    info masserot     process:ISYS_moni stopped
2020-04-08-07h46m00-UTC    info masserot     process:ISYSnoise stopped
2020-04-08-07h46m03-UTC    info masserot     process:ISYS_slow_pre stopped
2020-04-08-07h46m07-UTC    info masserot     process:ISYS_slow stopped
2020-04-08-07h46m15-UTC    info masserot     process:ISYS_Acl stopped

The RAW data fow is now 15MB/s and the RAW_FULL  at 41MB/s

FbmAlp level

As all the Automation servers and the Reconstruction servers  are stopped, it remains only few servers providing data the Frame merger FbmAlp:

• 3 Slow frame builders: FbsDet, FbsAlp and FbsVac
• 2 python servers: PyDAQ and PyHVAC
• and FbmMain

This plot show the FbmMain latency and  the ones of its frame providers where we can see that it latency is mainly due to the FbsDet one and sometime to the PyDAQ one.

PyDAQ

The PyDAQ compute the latency of the different data streams (RAW, RAW_FULL,RDS, TREND, RAW_BACK). It use the DAQ only as trigger to perform the stream latency computation and to make the result available in the DAQ. To reduce it latency, it can be connected to an upstream server:

• FbmFE  from 2020-04-07-14h20 to 2020-04-07-15h05
• FbsMoni since 2020-04-07-15h05 . The FbsMoni configuration has been modified to provide an frame stream ouput in the /dev/shm/VirgoOnline directory.

The improvement for PyDAQ latency can be seem in this plot

FbsDet

This plot show the relationship between the FbsDet latency and the FbmAlp one . Thanks  to the monitoring performed by the Fbs server, the culprits were easily identified: the SDB power monitoring servers , the SIB2, SDB2 and SNEB ones.

Using the advance request facility for these servers it was possible to reduce the FbsDet latency by 1s and to have FbmAlp latency independent of the FbsDet one . The operation was done around 2020-04-06-21h00UTC (see this plot )

During these operation the RdsFbm_20 server crashed and was not restarted quickly as consequence 1020s of data are missing in the RDS stream

2020-04-06-21h11m25-UTC>WARNING-FdIOGetFrame: miss 1020 seconds between 1270241640.0 and 1270242660.0

FbmMain level

This plot show the latency of its different frame providers, mainly the 50Hz processing servers,  where one can see that the FbmMain latency is due to  50Hz processing of the Injection channels (INJ_50Hz server).

It appears that for the  INJ_50Hz server  there is a lot of channels sampled at high frequency, Fs>100kHz  which are ended with the "_FS" suffix  .

Removing the channels stored only in the RAW_FULL stream from the online 50Hz computation allows to reduce by 0.2s the latency at  the FbmMain level.

This operation was done the 2020-04-07-08h50UTC.(plot)

DAQ status

This plot show

• the online latency close to 2s at FbmAlp level without Automation servers running
• the online data flow, around 63MB/s
• and
  • the RAW_FULL stream flow at 42MB/s  or not  83MB/s as reported in the logbook 48896
  • the RAW stream flow at 18MB/s

As consequence for the online disk buffers

• raw_back 36TB , so 24days with an input data flow of 18MB/s
• raw_full 50TB, so 14days with an input data flow of 42MB/s

Conclusions

For the processing servers before the Automation level, if they don't use the 50Hz channels, it s better if they take their data for FbmFE  or for an upstream server with a  /dev/shm facility..

Maybe all the PyALP servers in the Automation VPM subsystem could use at least FbmFE instead of FbmMain .

The 2020-04-07-12h04UTC the PyHVAC server was restarted with as Frame input the FbsMoni /dev/shm .

Today, during the periodic checks tour I have verified the INJ Particle Counter which was always giving zero counting. After some verifications I have swapped the CEB counter (partcount5) with the INJ one (partcount3) and the situation will be kept monitored.

I also reset the Particle Counter at WEB (partcount7) since it was providing a flat reading in the last weeks. Data seems fine after the reset (See Fig. 1)

Here attahed are acoustic noise transfer functions and projections computed with the injections performed on March 26 and  on March 28:

• Figure 1 and first attached file: noise projection and TF in CEB hall with SQZ engaged
• Figure 2 and second attached file: noise projection and TFin CEB hall with SQZ shutter closed
• Figure 3 and 3rd attached file: noise projection and TF in Detection LAB with SQZ engaged
• Figure 4 and 4th attached file: noise projection and TF in Detection LAB with SQZ shutter closed

The difference with standard LN3+SQZ condition and that with SQZ shutter closed is a bit reduced projection and TF around 50Hz and 160Hz

Also attached is the matlab file to read the TF file and plot the data.

Today, around 15:35 UTC, I have restarted all the Moni processes with a new version of Moni package which allows the Moni flags to be computed as if META_ITF_LOCK_index=1, when the channel META_ITF_LOCK_index is missing. In the previous Moni version, all the flags itfState-dependent were grey when META_ITF_LOCK_index was missing.

Later on March 29 2018 an intervention to fix the SNEB doors was finished. Around thes days the correction on BL_V jumped from -4V to -8V, see figure 1.

This correspond to a rebalancing of the bench on March 27 and March 29 (see log file below). The balancing was probably done by looking at the control loop correction signals, instead of the signals actually send in the coils. Which means that the balancing put the signal sent into the BL_V coil roughly at the offset constant left by mistake a year before. The right course of action is to keep the BL_V offset at zero, and once the beam in the north arm is found again, redo the bench balancing using the motorized counterweight (which should bring it back to the middle of the range).

SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h53m52-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 100 steps forward
SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h54m08-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 400 steps forward
SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h54m32-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 2000 steps forward
SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h54m49-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 2500 steps forward
SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h55m24-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 10000 steps forward
SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h56m42-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 10000 steps forward
SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h56m59-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 10000 steps forward
SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h57m18-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 10000 steps forward
SNEB_Pico_2018-03-27-14h52m35-UTC.log:2018-03-27-14h58m27-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 10000 steps forward
SNEB_Pico_2018-03-29-07h16m29-UTC.log:PMC_MOTOR SNEB_NS    7 1
SNEB_Pico_2018-03-29-07h16m29-UTC.log:2018-03-29-07h17m11-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 10000 steps backward
SNEB_Pico_2018-03-29-07h16m29-UTC.log:2018-03-29-07h18m18-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 10000 steps backward
SNEB_Pico_2018-03-29-07h16m29-UTC.log:2018-03-29-07h18m29-UTC>INFO...-PicoControl> Motor 'SNEB_NS' moved 10000 steps backward

This offset has been added in May 2017, see figure 1. It seems to have happened during work on comparing SNEB to SWEB that was done on May 9, see figure 2. The trend data for May 9 are missing, so we only have the information for the day before and after.

Looking at figure 1, the correction signal changed for BL_V and FR_V by about 4V. These are coils at opposite end of the bench, and checking the configuration they have the same sign of actuation. So this change in correction correspond to an offset on BL_V being compensated by the same force applied on FR_V to have a zero angular force, but some force pushing the bench up or down (I am not sure of the sign).

I expect this is an offset left on by mistake after testing the sign of the actuation for the 4 vertical coils, and it is better to keep the offset at 0 (and if confirmed use the balancing mass on SNEB to keep the correction closer to zero too).

I have checked the other suspended benches. And the only remaing non zero offsets are for SDB1, they are 4 equal horizontal offsets, which correspond to a TY force. Presumably this is a torsion on the three supension wires to keep the bench roughly aligned with the beam even when the controls are off. Presumably it would be better to move that feedback offset up the suspension chain, and have it applied on the marionette coils, especially because the marionette is suspneded only from 1 wire and from 3 wires like the bench.

Today we noticed that there was an offset of 8V left on the coil SNEB_LC_COIL_BL_V. It has been removed at 12h54 utc for the standalone state. We will put it back when normal operations are restored.

To reduce the number of useless or empty plots in the VIM pages, I have reconfigured and restarted the processes MdVim and MdDQ.
Let me know if you observe in VIM pages some plots that are not updated anymore but that you still need for monitoring during this shutdown period.

These channels are acquired at 100kHz  and with the renaming they are now stored in the RAW_FULL stream

• 2020-04-03 07h34m53 UTC    SDB_EDB_dbox_rack saved - masserot: add the suffix _FS on the channels EDB_B1s1_PD1_{Audio,DC}_raw acquired at 100KHz (rev. 92665)
• 2020-04-03 07h35m09 UTC    Reconfigure EDB_MezzPD in SDB_EDB_dbox_rack

In order to reduce the data flow stored in the RAW_FULL stream and in the RAW stream, the following processes were stopped and made as optional in the VPM configuration file:

2020-04-02-09h22m11-UTC    info masserot     process:SWEB_PSD_sensing stopped
2020-04-02-09h22m20-UTC    info masserot     process:SWEB_Quadrants stopped
2020-04-02-09h22m27-UTC    info masserot     process:SWEB_Photodiodes stopped
2020-04-02-09h24m34-UTC    info masserot     process:SNEB_PSD_sensing stopped
2020-04-02-09h24m36-UTC    info masserot     process:SNEB_Quadrants stopped
2020-04-02-09h24m37-UTC    info masserot     process:SNEB_Photodiodes stopped
2020-04-02-09h26m14-UTC    info masserot     process:SDB2_Readout stopped
2020-04-02-09h26m25-UTC    info masserot     process:SDB2_Quadrants stopped
2020-04-02-09h26m28-UTC    info masserot     process:SDB2_Photodiodes stopped
2020-04-02-09h31m12-UTC    info masserot     process:SPRB_Photodiodes stopped
2020-04-02-09h31m16-UTC    info masserot     process:SPRB_Quadrants stopped
2020-04-02-09h31m30-UTC    info masserot     process:SDB2_spy stopped
2020-04-02-09h32m52-UTC    info masserot     process:SIB2_Photodiodes stopped
2020-04-02-09h32m53-UTC    info masserot     process:SIB2_Quadrants stopped
2020-04-02-09h35m20-UTC    info masserot     process:SUSP_rd stopped
2020-04-02-09h38m11-UTC    info masserot     process:SQZ_CC_Ctrl stopped
2020-04-02-09h39m38-UTC    info masserot     process:SQZ_CC_noise stopped
2020-04-02-09h57m01-UTC    info masserot     process:HInjector stopped
2020-04-02-09h57m02-UTC    info masserot     process:HRecPD2 stopped
2020-04-02-09h57m03-UTC    info masserot     process:HRecPD1 stopped
2020-04-02-09h57m04-UTC    info masserot     process:HRecClean stopped
2020-04-02-09h57m39-UTC    info masserot     process:FreeMich_Rec_B1pPD2_DC_20kHz stopped
2020-04-02-09h57m39-UTC    info masserot     process:FreeMich_Rec_B1pPD1_DC_20kHz stopped
2020-04-02-09h57m40-UTC    info masserot     process:FreeMich_Rec_B1pPD2_DC stopped
2020-04-02-09h57m41-UTC    info masserot     process:FreeMich_Rec_B1pPD2 stopped
2020-04-02-09h57m42-UTC    info masserot     process:FreeMich_Rec_B1pPD1_DC stopped
2020-04-02-09h59m22-UTC    info masserot     process:HRec stopped

2020-04-02-09h59m23-UTC    info masserot     process:FreeMich_Rec stopped

2020-04-02-10h17m06-UTC    info masserot     process:EPRB_PC stopped
2020-04-02-10h17m07-UTC    info masserot     process:EDB_PC stopped
2020-04-02-10h17m08-UTC    info masserot     process:EIB_PC stopped

The RAW_FULL data flow is now arround 83MB/s and the RAW data flow around 18MB/s

Following the ITF stop,
On Tuesday 2020-03-31 around 13:00 UTC, I stopped the process SegOnline that sends DQ flags segments to DQSEGDB.
Today around 09:30 UTC, I changed the configuration of SpectroMoni, so that data needed for spectrograms in VIM are stored only for Environment and Suspensions.

The NoEMi SFDB launcher and line-finder tool was stopped following its daily run yesterday morning; the 1st of April.

The O3 dataset was closed following the run on Saturday morning, the 28th of March, and the post-O3 dataset was opened. NoEMi has been run from the date of the suspension until yesterday morning and the results can be found in this new dataset. O3 remains, of course, fully available - along with O2, ER14 and ER13. All are available via the web interface:

https://apps.virgo-gw.eu/noemi/

I stopped the following ACL processes to reduce the stored data flow and I marked them as optional in VPM, to stop them from appearing red:

2020-04-02-05h05m16-UTC   process:SSFS_Ctrl stopped
2020-04-02-05h05m17-UTC   process:SSFS_noise stopped
2020-04-02-05h05m18-UTC   process:SSFS_phi stopped

2020-04-02-05h16m14-UTC    process:LSC_Acl_Moni stopped
2020-04-02-05h19m09-UTC    process:LSC_Acl stopped
2020-04-02-05h19m09-UTC    process:ASC_Acl stopped
2020-04-02-05h19m12-UTC    process:CALnoise stopped

The same operation may be done for the SQZ coherent control loop, the PCAL loops

The attached plot show some DAQ monitoring channels since the  2020-03-31

• first row: online latency
• second row: online nAdc
• third row: storage RAW_FULL data flow and storage RAW data flow

I've stopped the dail-bruco scripts. They were run from the vrigorun's crontab on the detchar1 (olserver141) machine. To restart them - uncomment three lines in the crontab.