Differences between revisions 1 and 12 (spanning 11 versions)

Angular Sensing and Control (Oct, 2022)

Contents

Angular Sensing and Control (Oct, 2022)
Next Steps
Known issues

WFS ports

REFL (17, 45 MHz)

Optical layout
- https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=9238
- Same as O3GK
PZT1, PZT2, and REFL_WFS picomotors are available to center the beam on REFL_WFS1 and REFL_WFS2

POP (17, 45 MHz)

Optical layout
- https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=9623
- POP WFSs were newly installed after O3GK
POP-S and POP-P cameras are available

AS (17, 28 MHz)

Optical layout
- https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=9817
- Mostly same as O3GK
PZT1, PZT2, and AS_WFS picomotors are available to center the beam on AS_WFS1 and AS_WFS2
AS and OMC_TRANS CCDs are available
OMC_REFL CCD hasn't been connected

DC QPD ports

TMSX

There is only QPD2 (K1:TMS-X_IR_QPDA2_{PIT,YAW}) on the TMSX in-air path. At a random Gouy phase position.
The beam was sent to the QPD2 when the X-arm is locked, but the X-arm alignment may have changed since then.
TMSX in-air table power budget
- https://klog.icrr.u-tokyo.ac.jp/osl/?r=22310
The in-air beam is extremely astigmatic
- https://klog.icrr.u-tokyo.ac.jp/osl/?r=22221
There are strong PIT-YAW coupling depending on the position of the beam
- https://klog.icrr.u-tokyo.ac.jp/osl/?r=22228
- Matteo-san's previous measurement did not show a strong coupling. It seems to depend on the position of the DC QPDs.
  - https://klog.icrr.u-tokyo.ac.jp/osl/?r=20263

TMSY

TMSY QPD1 and 2 are placed on the TMSY in-air table, with 90 degrees separated in Gouy phase
QPD1 is used to the beam position control feeding back to the BS (K1:ASC-DOF1_{P,Y})
Beam profile
- https://klog.icrr.u-tokyo.ac.jp/osl/?r=22479
No PIT-YAW coupling
- https://klog.icrr.u-tokyo.ac.jp/osl/?r=22575

POP Forward

There are two DC QPDs on POP Forward, used for the initial alignment

DC PDs

There are POP_P and POP_S DC PDs on POP.

WFS Commissioning

WFS DC centering

General

If the beam is off, use the picomotor first because the PZT ranges are not large
Beam spots on the quadrant diodes must be centered (DC centering)
- PZTs and picomotors are available

REFL

Open the REFL shutter first for REFL WFS
K1:ASC-DC5_{P,Y} are used for the DC centering controls

POP

DC control loop not implemented yet

AS

DC control loop not implemented yet

Single Y arm

Sensing matrix
- https://klog.icrr.u-tokyo.ac.jp/osl/?r=22578
Input matrix
- https://klog.icrr.u-tokyo.ac.jp/osl/?r=22602
Loops closed
- https://klog.icrr.u-tokyo.ac.jp/osl/?r=22671
- K1:ASC-DSOFT_{P,Y} to IY
- K1:ASC-DHARD_{P,Y} to EY
Loops or noise haven't been characterized
No offsets were necessary on the sensors

Single X arm

PRMI

PRFPMI

DRFPMI

Next Steps

Infrastructure

Guardian implementation
- DC centering loops on REFL, POP, and AS
- Single Y, X arms, and PRMI guardstates for initial alignment
Add trigger for the main ASC switch (K1:ASC-WFS_GAIN) similarly to the IMC switch (K1:IMC-WFS_GAIN)

Simulation

Compare the measured sensing matrices against the simulation
- Koyama-kun's simulation GUI tool is available on the workstations
  - sitemap > Commissioning Top > finesse GUI

Integration

Implement single-Y, single-X, and PRMI controls for the initial alignment
- If the alignment is too off, first ADS then WFS control?
PRFPMI/DRFPMI angular controls
Noise budget

Known issues

TMSX PIT-YAW coupling
- The beam is slightly not centered in yaw on the second lens on the in-air table. Adjusting the beam position on the lens might fix the problem.

KAGRA/Subgroups/MIF/AngularSensing (last edited 2022-11-02 09:12:15 by KeikoKokeyama)

-  ⇤ ← Revision 1 as of 2022-10-26 08:55:49 → 
  Size: 1468
  Editor: KeikoKokeyama
  Comment:
+   ← Revision 12 as of 2022-10-26 11:01:18 → ⇥
  Size: 4031
  Editor: KeikoKokeyama
  Comment:
-Deletions are marked like this.
+Additions are marked like this.
 Line 1:
-= Angular Sensing and Control (2022) =
+= Angular Sensing and Control (Oct, 2022) =

<<TableOfContents()>>
-Line 5:
+Line 7:
-=== REFL ===
+=== REFL (17, 45 MHz) ===
-Line 8:
+Line 10:
- * REFL PZT1, REFL PZT2, and REFL_WFS picomotors are available to center the beam on REFL_WFS1 and REFL_WFS2
+  * Same as O3GK
 * PZT1, PZT2, and REFL_WFS picomotors are available to center the beam on REFL_WFS1 and REFL_WFS2
-Line 11:
+Line 14:
-=== POP ===
+=== POP (17, 45 MHz) ===
-Line 14:
+Line 17:
+  * POP WFSs were newly installed after O3GK
-Line 15:
+Line 19:
- * POP PZT1, POP PZT2, and POP_WFS picomotors are available to center the beam on POP_WFS1 and POP_WFS2
-Line 17:
+Line 20:
-=== AS ===
+=== AS (17, 28 MHz) ===
 * Optical layout
  * https://gwdoc.icrr.u-tokyo.ac.jp/cgi-bin/private/DocDB/ShowDocument?docid=9817
  * Mostly same as O3GK
 * PZT1, PZT2, and AS_WFS picomotors are available to center the beam on AS_WFS1 and AS_WFS2
-Line 23:
+Line 31:
+=== TMSX ===
 * There is only QPD2 ({{{K1:TMS-X_IR_QPDA2_{PIT,YAW}}}}) on the TMSX in-air path. At a random Gouy phase position.
 * The beam was sent to the QPD2 when the X-arm is locked, but the X-arm alignment may have changed since then.
 * TMSX in-air table power budget
  * https://klog.icrr.u-tokyo.ac.jp/osl/?r=22310
 * The in-air beam is extremely astigmatic
  * https://klog.icrr.u-tokyo.ac.jp/osl/?r=22221
 * There are strong PIT-YAW coupling depending on the position of the beam
  * https://klog.icrr.u-tokyo.ac.jp/osl/?r=22228
  * Matteo-san's previous measurement did not show a strong coupling. It seems to depend on the position of the DC QPDs.
   * https://klog.icrr.u-tokyo.ac.jp/osl/?r=20263
-Line 25:
+Line 47:
+ * QPD1 is used to the beam position control feeding back to the BS ({{{K1:ASC-DOF1_{P,Y}}}})
 * Beam profile
  * https://klog.icrr.u-tokyo.ac.jp/osl/?r=22479
-Line 28:
+Line 53:
-=== TMSX ===
+=== POP Forward ===
 * There are two DC QPDs on POP Forward, used for the initial alignment
-Line 30:
+Line 56:
+== DC PDs ==
 * There are POP_P and POP_S DC PDs on POP.
-Line 34:
+Line 61:
-Line 35:
+Line 63:
- * Open the REFL shutter for REFL WFS
+==== General ====
 * If the beam is off, use the picomotor first because the PZT ranges are not large
-Line 38:
+Line 67:
+==== REFL ====
 * Open the REFL shutter first for REFL WFS 
 * {{{K1:ASC-DC5_{P,Y}}}} are used for the DC centering controls
==== POP ====
 * DC control loop not implemented yet
==== AS ====
 * DC control loop not implemented yet
-Line 46:
+Line 83:
-  * DSOFT is IY, DHARD is EY 
 * Loops or noise haven't been characterized
+  * {{{K1:ASC-DSOFT_{P,Y}}}} to IY
  * {{{K1:ASC-DHARD_{P,Y}}}} to EY
 * Loops or noise haven't been characterized
 * No offsets were necessary on the sensors
-Line 59:
+Line 98:
+= Next Steps =
== Infrastructure ==
 * Guardian implementation
  * DC centering loops on REFL, POP, and AS
  * Single Y, X arms, and PRMI guardstates for initial alignment
 * Add trigger for the main ASC switch ({{{K1:ASC-WFS_GAIN}}}) similarly to the IMC switch ({{{K1:IMC-WFS_GAIN}}})
== Simulation ==
 * Compare the measured sensing matrices against the simulation
  * Koyama-kun's simulation GUI tool is available on the workstations
   * sitemap > Commissioning Top > finesse GUI
== Integration ==
 * Implement single-Y, single-X, and PRMI controls for the initial alignment
  * If the alignment is too off, first ADS then WFS control?
 * PRFPMI/DRFPMI angular controls
 * Noise budget

= Known issues =
 * TMSX PIT-YAW coupling
  * The beam is slightly not centered in yaw on the second lens on the in-air table. Adjusting the beam position on the lens might fix the problem.