Reports of 31047
MIF (General)
takaaki.yokozawa - 8:16 Saturday 26 April 2025 (33563) Print this report
Tweak the INP2_P and PRC2_P offset
For the tapping test today, I tweaked the offset values for the INP2_P and PRC2_P
Previous evaluation by Komori-san group was written in klog33501, INP2_P=-1.6, PRC2_P=0.14.
For my several tweaking, INP2_P=-1.2, PRC2_P=0.12.
If we increased the offset more, locked loss happened in several times.
After setting those values, we performed the OMC alignment using PRFPMI RF.

Images attached to this report
MIF (General)
Shu-Wei Yeh - 1:21 Saturday 26 April 2025 (33562) Print this report
Noise Subtraction at 116 Hz and 161 Hz on April 16
[Shu-Wei Yeh, Chia-Jui Chou]

We performed noise subtraction using DeepClean on strain data from April 16. The witness channel used was K1:LSC-REFL_PDA3_RF45_I_ERR_DQ.

Coherence between the witness channel and the strain channel was evaluated using data from the Silent Run state on April 16 (GPS 1428842445) over a 1024-second interval. High coherence was observed at 116 Hz and 161 Hz (Figure 1).

DeepClean was applied at these frequencies, and the improvement in inspiral range was evaluated. The training segment started at GPS 1428842445 with a duration of 4096 seconds, and the cleaning segment began at GPS 1428846541, also with a duration of 4096 seconds.

Band-pass filters (BPFs) were applied to isolate and test the noise subtraction performance:

- 116 Hz: 114 Hz – 119 Hz
- 161 Hz: 155 Hz – 165 Hz

Figure 2 shows that using the 114–119 Hz BPF yielded good performance, with an inspiral range improvement of 0.244889%.
Figure 3 shows similarly promising results for the 155–165 Hz BPF, with an improvement of 0.264625%.

The next step is testing coherence and DeepClean performance using the upcoming Silent Run data.
Images attached to this report
DGS (General)
shoichi.oshino - 17:05 Friday 25 April 2025 (33561) Print this report
NAS maintenance
I updated the firmware on k1nfs2 to the latest version.
Also, several applications are updated.
ZFS scrub was performed on the backup server storage.
No errors have occurred on these storages.
VIS (General)
takafumi.ushiba - 16:56 Friday 25 April 2025 (33558) Print this report
Consideration on actuator noise due to DC current

Abstract:

Coil driver output voltage noise might be comparable with the shot noise of the effective current applied to the coils.
If so, further actuator efficiency reduction, except for ETMX, might not be effective to reduce actuator noise and reducion of RMS of the feedback signals would reduce it..

Detail:

I evaluated the effect of shot noise from DC current applied to actuator coils.
According to fig1, RMS pf TM actuator feedback signals during OBSERVATION state are roughly 6000 cnts for ETMX, 2000 cnts for ITMY, 1500 cnts for ETMY, and 2500 cnts for ITMX.
If we considered effective current as 1/sqrt(2) of RMS, effective current for each suspensions can be calculated as follows:
ETMX: 6000 [cnt] * 310e-6 [V/cnt] / sqrt(2) / 150 [Ohm] = 8.8 mA
ITMY: 2000 [cnt] * 310e-6 [V/cnt] / sqrt(2) / 300 [Ohm] * 2 = 2.9 mA (last 2 is a compensation gain, which was engaged after reduction of actuator efficiency to keep the actuator gain from COILOUTF input)
ETMY: 1500 [cnt] * 310e-6 [V/cnt] / sqrt(2) / 300 [Ohm] * 2 = 2.2 mA
ITMX: 2500 [cnt] * 310e-6 [V/cnt] / sqrt(2) / 300 [Ohm] * 2 = 3.7 mA

So, shot noises of the current applied to TM coils are 5.3e-11, 3.0e-11, 2.7e-11, and 3.4e-11 A/rtHz for ETMX, ITMY, ETMY, and ITMX, respectively.
Here, I used sqrt(2*e*I), which is the relation between shot noise and DC current, where e is an elementary charge and I is effective current applied to coils.
If we considered 1e-8 V/rtHz of HPCD output voltage noise, current noises applied to the coil are 6.7e-11 A/rtHz for ETMX and 3.3e-11 A/rtHz for the others, which is close to the estimated shot noise of the effective current.

If the above consideration is true and voltage noise and current noise is independent (summation of the noise can be calculated by square root of square sum), actuator efficiency reduction by inserting resistance reduces actuator noise by a factor of 1.3, which is slightly lower than we expected (1.5) by only considering coil driver output noise.
Also, current noise cannot be reduced by reducing actuator efficiency, so further actuator efficiency reduction, except for ETMX, might not be effective to reduce the actuator noise, and reduction of RMS of feedback signals might reduce the actuator noise.

Note:

Since I'm not so sure using effective value of the current is suitable for calculating the shot noise, my discussion would be wrong.

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DGS (General)
satoru.ikeda - 16:40 Friday 25 April 2025 (33560) Print this report
Preparing to replace the IO chassis of K1TEST0 with a new IO chassis

[Oshino-san, YamaT-san, Ikeda]

Summary
Several problems involving IO chassis have been reported. (K-Log#33348,#16759)
The old IO chassis's use HIB cards, but there are no replacement cards in stock.
Therefore, replacement with a new IO chassis is mandatory for the future.
The DGS has confirmed that a configuration equivalent to K1TEST0 will run for a long time on the test bench.
First, we will replace K1TEST0 with the new IO chassis to investigate the impact on KAGRA.

Details
We prepared to replace the IO chassis of K1TEST0 with a new IO chassis(S2416128).

The DC cables we have on hand have different terminal configurations, so we returned to the old IO chassis.
The placement within the rack is tentative.
K1TEST0 and the old I/O chassis have been moved slightly upward within the rack.

The BIOS of K1TEST0(V3) was Version 3.1.
The test bench results confirm that 3.1 recognizes four Adnaco cards.
With 1.0, only one card was recognized.

We plan to replace it with a new IO chassis next week.
 

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MIF (General)
hirotaka.yuzurihara - 15:23 Friday 25 April 2025 (33559) Print this report
The recent interferometer is sensitive to the weak seismic motion or not

[Guo Chin, yuzu]

Motivation

Ushiba-san pointed out the hypothesis that the recent interferometer is sensitive to seismic motion, that weak seismic motion can lead to oscillation of the IMC length, and that frequent lockloss with IMCL label occurs. We want to test this hypothesis by comparing the lockloss data between 10 W operation and 1.2 W operation.

Data set

We focused on the lockloss from the OBSERVATION_WITHOUT_LINES (called silent run) and lockloss with the IMCL labels, because it's easy to find the lockloss related to the excess of the seismic motion (3~10 Hz).

The data in two kinds of periods were checked.

  • 10 W operation: 2025/04/06 ~ 04/21
  • 1.2 W operation: 2025/12/24 ~ 12/30, 2025/02/10 ~ 02/18 

Result

During 10 W operation, there were 21 lockloss with the IMCL label. 19 lockloss coincided with an excess of the seismic motion of 1~10 Hz bands.
During 1.2 W operation, there were 16 lockloss with the IMCL label. 6 lockloss coincided with an excess of the seismic motion of 1~10 Hz bands.

We collected the seismic motion data of the 3~10 Hz band around the lockloss. Actually, we checked both frequency bands of 1~3 Hz and 3~10 Hz. The excess of the 3~10 Hz frequency band looks to be the dominant source of the oscillation of the IMC length.
In some cases, we observed the two-step peaks due to the p-wave and s-wave (for example, the lockloss of 2024/12/28 19:36:42 UTC), and we recorded the peak value closer to the lockloss.
Figures 1~5 show the time series around the lockloss and peak value of the seismic motion.

Figure 6 shows the histogram of the peak amplitudes for two periods.
In the case of 10 W operation, even though the seismic motion is small, such as < 0.5 um/s, the oscillation of IMC length frequently occurred, and the lockloss occurred.
In the case of 1.2 W operation, the IMC length oscillation didn't happen frequently. It makes a smaller number of lockloss with the IMCL label (6 times).

Next week, I will plan to check the seismic motion of 3~10 Hz during lock and collect the excess of 3~10 Hz data that didn't make the lockloss. We can test the hypothesis if we collect many examples where the lock continued even though there was an excess of 3-10 Hz seismic motion, in 10 W operation.
And also, I will check the frequency of occurrence of the excess 3~10 Hz at 2024/12, 2025/02, and 2025/04. It's possible that the seismic motion of 3~10 Hz occurred frequently in April.

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IOO (General)
kenta.tanaka - 12:33 Friday 25 April 2025 (33553) Print this report
Phase rotator implement to be able to compensate relative phase between coils for beacon excitation

Ikeda, Tanaka

As reported in klog32957, the relative phase between each coil of the beacon excitaion seems not to be in phase maybe due to the steep phase rotation in 24 kHz modified AI filter. So we implemented phase rotator for each coil of beacon excitation to be able to compensate relative phase difference due to the phase rotation by 24 kHz modified AI filter.

Fig. 1 shows the new medm screen of beacon excitation. We add the phase rotator function between EUR2COIL and COILOUTF. Now, we use the SIN output as the beacon excitaion signal instead of CLK. So if you want to change the excitation amplitude, you input the value not in CLKGAIN but in SINGAIN. Fig.2 shows the screen of the rotator. Then, if you input the same value in COSGAIN as the one in SINGAIN, the rotator shifts the phase of the beacon signal applied the coils to the value in K1:SEN-{TypeA TM name}_H{1,2,3,4}_PHASE_R.

I tested the function. The left lower panel in Fig. 3 shows the phase transfer function at 23605.5 Hz between H1 and others and the phase configuration. As you can see, the rotator shifted the phase to the value which we set.

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CAL (General)
hirotaka.yuzurihara - 12:32 Friday 25 April 2025 (33557) Print this report
TCam photo session 20250425
VIS (BS)
satoru.ikeda - 11:56 Friday 25 April 2025 (33555) Print this report
Comment to Engage dewhitening filter for BS (33518)

Update model files

Request from Ushiba-san
[K1BS, K1SR2, K1SR3, K1SRM]
model: k1visbst, k1vissr2t, k1vissr3t, k1vissrmt

Modifications
BS and SR change all GAS and IP BIO connections to the same connection.
 GAS: H32_C2
 IP: L32_C2
TOWER_MASTER/TPPEB_TOWER_MASTER
 Modify input to COILOUT_CTRL,MASK of F0 from IP_COILOUTF_CTRL,MASK to GAS_COILOUTF_CTRL,MASK.
 

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DGS (General)
satoru.ikeda - 11:55 Friday 25 April 2025 (33556) Print this report
Update model files

Request from K.Tanaka-san
[K1EX1, K1EY1, K1IX1, K1IY1]
model: k1sendbeacon, k1sendbeaconey, k1sendbeaconix, k1sendbeaconiy

Modifications
BEACON_LIB/BEACON_SENDER
 Input to LOMON was changed from CLK of OSC to SIN.
 Added PHASE as an input to COS of OSC before input to COILOUTF.
k1sendbeacon
 Replaced with BEACON_SENDER.
 

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VAC (Tube Y)
nobuhiro.kimura - 11:55 Friday 25 April 2025 (33554) Print this report
Comment to Water chiller for TMP at Y27 (33528)

[Kimura and Yasui]
 A lack of cooling water was found in the chiller unit for TMP in Y-27, so the cooling water in the other chiller units was checked for water quantity.
As a result, a cooling water shortage was also found in the chiller unit for TMP of X-10.
Therefore, approximately 3.5 L of water was added to the water tank inside the chiller unit.
 (See attached photos)

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PEM (Center)
tatsuki.washimi - 9:47 Friday 25 April 2025 (33552) Print this report
Comment to Check the reproducibility of the aoustic injection around OMC area (33551)

up + down

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VAC (EX)
nobuhiro.kimura - 9:05 Friday 25 April 2025 (33547) Print this report
Installation of an interlock circuit in the #-39 pumping unit at X-end

[Kimura and Yasui]

 We installed an interlock circuit in the #-39 pumping unit at X-end on Apr. 24..
After installation, we confirmed that the interlock circuit works in the event of a power failure and that the shutoff valve between the dry pump and the TMP is closed.
After this operational test, the gate valve between the pumping unit and the duct was opened and the TMP of the #-39 pumping unit started pumping.

 We also installed blue and red double-sided magnetic sheets to indicate operating status of vacuum pumps.
The blue side of the magnetic sheet indicates " operation", while the red side indicates " shutdown".

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PEM (Center)
takaaki.yokozawa - 8:59 Friday 25 April 2025 (33551) Print this report
Check the reproducibility of the aoustic injection around OMC area
[YokozaWashimi]

To check the reproducibility of the result of the acoustic injection around the OMC are, we took following data

8:25:30 - 8:50:30 sweep 100cnt 80 - 120 Hz (up) using 300 s (totally 5 loops)
8:50:30 - 9:00:30 sweep 100cnt 80 - 120 Hz (down) using 300 s (totally 2 loops)
Images attached to this report
Comments to this report:
tatsuki.washimi - 9:47 Friday 25 April 2025 (33552) Print this report

up + down

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MIF (General)
takaaki.yokozawa - 8:49 Friday 25 April 2025 (33550) Print this report
Compared the DARM spectrum between shaker and OMC LSC pzt
To evaluate the noise projection from OLC-LSC error to DARM, I compared the result using the large shaker at OMC floor and pzt for the OMC LSC.

Large shaker at OMC floor : K1:PEM-EXCITATION_SR3_RACK_7_EXC
pzt for the OMC LSC : K1:OMC-PZT_HV1_EXC

I excited the shaker at the 100 or 200 cnt, and adjust the output cnt for pzt case
Freq : cnt shaker : cnt pzt
82 Hz : 100 : 114
85 Hz : 200 : 8
90 Hz : 100 : 27
95 Hz : 100 : 22
100 Hz : 100 : 126
105 Hz : 200 : 7

Fig.1. - Fig.6. showed the result of the spectrum
Top : DARM displacement
Middle : OMC LSC error
Bottom : OMC LSC error (low frequency)
(Blue)silent (Green)Shaker (red)pzt

As you can see,
in 85, 90 and 105 Hz
There are signal in shaker case, but no signal in pzt case in the linear frequency

In 95 Hz
Small amplitude in linear frequency and there are side band

in 82 and 100 Hz
Larger sideband signal can be seen in DARM and shape is very similar
 
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MIF (General)
hirotaka.yuzurihara - 8:44 Friday 25 April 2025 (33549) Print this report
Comment to Comparison of number of IMCL labels between 1.2 W and 10 W operation (33538)

> My guess to explain this result
A day later, I read this description again. But, I don't understand it. Please ignore this explanation.

PEM (Center)
takaaki.yokozawa - 8:36 Friday 25 April 2025 (33548) Print this report
PEM injection test 250425
I performed the PEM injection this morning.

PEM injection using large shaker at OMC floor
2025/04/25 05:20:00 - 05:50:00
Excitation : K1:PEM-EXCITATION_SR3_RACK_7_EXC
50 - 200 Hz , 1Hz resolution, 10 s in each measurement, 100 cnt

PEM injection using large shaker at OMC floor
2025/04/25 05:51:00 - 06:31:00
Excitation : K1:PEM-EXCITATION_SR3_RACK_7_EXC
200 - 400 Hz , 1Hz resolution, 10 s in each measurement, 100 cnt

PEM injection using OMC speaker
2025/04/25 06:33:00 - 07:10:00
Excitation : K1:PEM-EXCITATION_SR3_RACK_6_EXC
50 - 900 Hz , 5Hz resolution, 10 s in each measurement, 100 cnt


IOO (OMC)
kenta.tanaka - 0:36 Friday 25 April 2025 (33546) Print this report
Trial of beacon ASC recovery

I tried to recover OMC ASC with beacon. I scanned ETMX and found the current drumhead frequency is 23605.5 Hz. Also I performed phasing for 17 MHz demodulation with this frequency and phasing for 24 kHz demodulation with OMMT2 PIT excitation at 0.5 Hz. Then I decoupled OMMT2 and OSTM dofs. But I will try to close the loops yet because today is already late.

Details will be reported later.

IOO (OMC)
takafumi.ushiba - 20:31 Thursday 24 April 2025 (33545) Print this report
Some consideration on OMC LSC noise coupling

[Tanaka, Ushiba]

Abstract:

Current OMC length fluctuation might be limited by sensing noise feedback through OMC PZTs.
So, it would be better to optimize OMC LSC to reduce the residual OMC length motions.

Detail:

Since OMC LSC residual motion was one of the large coupling path to the OMC transmission (klog30657 and klog30613), we evaluated current OMC length residual motion.
To evaluate the length motion, we used following two ways:
1. Length fluctuation by vibration of optical table
2. Length fluctuation by sensing noise through OMC LSC.

Length fluctuation by vibration of optical table

To evaluate the length fluctuation by #1 path, we measured transfer function from OMC geophone to OMC length fluctuation by white noise shaker injection.
We measured the transfer function of each 10Hz bands and combined it to avoid saturation.
OMC length was calibrated into displacement in the unit of meter by comering the condition with old optical efficiency measureent (klog30535).
Calibration factor of 5.1e9 cnt/m was obtained 300-cnt dither amplitude with 29mW OMC trans.
During the measurement, we used 30000-cnt dither amplitude with 30.5mW OMC trans.
Since the actuator efficiency of dither PZT was reduced by a factor of 10 due to the change of PZT driver for OMC DC PD protection (klog32549), calibration factor during the measurement is 5.1e9 *(30000/300)/10 * 30.5/29 = 5.4e10 cnt/m, which is 1.9e-11 m/cnt (note that current nominal OMC lock was done by 500-cnt dither amplitude, so calibration factor during the OBSERVATION state should be 1.1e-9 m/cnt).

Figure 1 shows the measured transfer function from optical table displacement measured by in-vac geophone to OMC error signals.
Bottom left and middle right show the TF from OMC geophone signals (calibrated into the unit of meter) to OMC error signals (also calibrated into the unit of meter) at 130-200 and 50-130 Hz, respectively.
Top right and bottom right shows the coherence between OMC error signals and geophone signals during the measurement.
By using these TF and geophone spectrum during the OBSERVATION state, we can estimate the OMC length fluctuation due to OMC stack vibration as shown in fig2 (blue).

Length fluctuation by sensing noise through OMC LSC

As discribed in the above, calibration factor of OMC error signals during the observation is 1.1e-9 m/cnt, so the current sensing noise of OMC error signals in the unit of meter can be plotted as shown in fig3.
Current UGF of the OMC LSC loop is about  9Hz (klog31780), so I made a OLTF model according to the filters implemented in K1:OMC-LSC_FB_FLT filter bank and calculated the OMC length fluctuation due to feedback of the sensing noise.
Figure 4 shows the result with OMC length fluctuation estimated from OMC geophone spectrum.
According to this calculation, current OMC length fluctuation seems to be limited by OMC LSC feedback noise upto 120Hz except for several peaks.
So, it might be worth trying to modify the OMC LSC loop to mitigate the OMC length fluctuation around 100Hz.

Note:

Currently, CARM noise coupling somehow increased and noise around 5kHz is larger than the best sensitivity.
So, reducing CARM coupling and improving the sensitivity around 5kHz also contributes to reduce the OMC length fluctuation through sensing noise reduction.

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MIF (ASC)
hirotaka.yuzurihara - 17:01 Thursday 24 April 2025 (33544) Print this report
Histogram of phenomena before lockloss (2025/02/10~04/21)

[Guo chin, Yuzu]
I made the histogram to count the phenomena before the lockloss between 2025/02/10 and 04/21.|
Recently, the number of the lockloss related to the IMC oscillation is the dominant phenomena. After 4/3, the lockloss related to the oscillation (saturation) of OMC drastically was mitigated.

This time, I focused on the lockloss from OBSERVATION_WITHOUT_LINES. Note that I counted the number manually. It's possible to shift the number a bit.

Important date for commissioning

  • 2/19 : 10 W operation started (klog#32748) (klog#32756)
  • 4/3: engaging whitening filters for GAS to mitigate the 20 Hz resonance kick by DAC noise (klog#33197)
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MIF (General)
hirotaka.yuzurihara - 16:43 Thursday 24 April 2025 (33538) Print this report
Comparison of number of IMCL labels between 1.2 W and 10 W operation

[Guo Chin, Yuzu]
We compared the number of lockloss with the IMCL label between 1.2 W and 10 W operation. The frequency of occurrence was 4.5 times per day during 1.2 W and 1.3 times per day during 10 W operation, respectively. This number is smaller than the number in the case of 1.2 W operation (last Feb.).

Details

  • For 1.2 W operation, we checked the data of 2025-02-10 14:19:50.312500 UTC ~ 2025-02-18 14:22:44.062500 UTC.
    • During this period, the number of the lockloss with the IMCL label was 3. The duration of OBSERVATION_WITHOUT_LINES (called silent run) is 57183 s.
    • The frequency of occurrence is evaluated as 4.5 times per day.
  • For 10 W operation, we checked the data between 2025-04-06 06:02:46.937500 UTC ~ 2025-04-21 16:50:17.687500 UTC.
    • The number of lockloss with the IMCL label was 21 in this period. The duration of OBSERVATION_WITHOUT_LINES (called silent run) is 506818 s.
    • The frequency of occurrence is evaluated as 1.3 times per day. This number is smaller than the number in the case of 1.2 W operation (last Feb.).

Note that we collected the lockloss only from OBSERVATION_WITHOUT_LINES (called silent run).

My guess to explain this result

  1. In Febrary, we didn't collect enough length of the silent run (~16 hours) with 1.2 W operation. As a result, we did't observe many lockloss (actually just 4 times) due to the oscillation of the IMC.
  2. After 10 W operation, we performed the interferometer as the silent run and collected enough data (~5.9 days). As a result, we observed the lockloss due to the oscillation of the IMC, many times.

We will summarize the comparison ot the ampitude to trigger the lockloss of the IMC oscillation,

Comments to this report:
hirotaka.yuzurihara - 8:44 Friday 25 April 2025 (33549) Print this report

> My guess to explain this result
A day later, I read this description again. But, I don't understand it. Please ignore this explanation.

PEM (Center)
tatsuki.washimi - 16:16 Thursday 24 April 2025 (33543) Print this report
Comment to PEM injection 250420 (33483)
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PEM (Center)
tatsuki.washimi - 16:08 Thursday 24 April 2025 (33542) Print this report
Comment to PEM injection 250420 (33483)
PEM (Center)
tatsuki.washimi - 14:53 Thursday 24 April 2025 (33540) Print this report
Comment to PEM injection 250420 (33483)

I analyzed the same analysis using SEIS_Z or ACC_Z and compared the results for both 2025-04-20 and 2024-11-09 data.
For both days, the results of using SEIS_Z and ACC_Z are consistent.

 

By the way, even before the shroud installation (2024-11-09), the linear-like coupling and its siderobe were found. 
On 2024-10-16 (before the stack connection), a ground shaker injection was performed (klog31337), but almost no significant excess was found in the DARM. (due to the shaking amplitude not being enough?)

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VIS (General)
takafumi.ushiba - 9:46 Thursday 24 April 2025 (33537) Print this report
Comment to Engaging dewhitening filter for Type-B tower (33531)

The reason of SR3 oscillation seems F1 GAS control.
Fgure 1 shows the F1 LVDT signals with nominal gain (blue), -3dB (green), and -6dB from the nominal (red).

Since -3dB and -6dB seems no significant difference, I engaged -3dB at FM7 of F1_DAMP_GAS filter bank.
Then, we can engage 2-stage dewhitening filters for SR3 tower as well as the other Type-B suspensions.

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