script_file = '../hallc_online/analysis/elastic/el_asym_{}.cxx'.format(args.command.lower())
   script_args='{},{},\"{}\"'.format(args.run, -1, args.mode)
   analysis_cmd = "root -b -q '{}+({})'".format(script_file, script_args)

   # -a "${ODIR}"/MON_OUTPUT/ANLYSIS_HISTOS/${2}/elastic1.png       <- this line
   # -a "${ODIR}"/MON_OUTPUT/ANLYSIS_HISTOS/${2}/elastic2.png       <- this line

"~/polhe3/production/hallc_online/analysis/elastic/el_asym_(s)hms.cxx"

 -h, --help           show this help message and exit
 -p MOMENTUM          momentum setting (GeV)
 -a ANGLE             angle setting (degree)
 -t TOLERANCE         absolute tolerance for settings
 --date-start START   start date
 --date-end END       end date
 --counts-min CMIN    minimum event counts for valid elastic runs
 --estimate ESTIMATE  estimated asymmetry for this setting (without any corrections)
 --factor-qe F_QE     dilution factor from Quasi-Elastic asymmetries
 --run-script         run count script if output does not exist

Necessary Prep work during Hall Controlled Access on Monday (schedule with RadCon in advance)

• Install collimators (JP, RadCon) [2]
• Check on EPR photo-diode status, likely replace it (RadCon)
• Let Hall B know that we will be changing IHWP status more often during this period
  • Likely every 2--4 hours (not 8 hours)
  • We will still let them know in advance.
• Ensure fast raster is reconfigured correctly (Expert: Jones, Gunning)
  • "Have MCC click on the button on the Expert page for 1 coil (instead of 2 coils). Ensure "gbeam_pass1_jan2020.param" is used for analysis"
  • Bill G support will support shut off / unplug one of the power supplies (Brad will follow-up)
  • Verify pattern using DAQ and random pulser (Brad)
• Rotate spectrometers to minimum angles for HMS (11.7) and SHMS (8.5) (S. Lassiter, A. Comer)
  • Confirm we can rotate them away from the beamline remotely
• Pressure curve questions
  • Pump Reference cell to vacuum while waiting for Sweep in the morning
  • Open He3 bottle just before locking up Hall
  • Complete reference cell runs after we come back up (following Beam energy meas.)
  • Escorted access to Hall after ref cell running complete to close valves at He3 cylinder (Opportunistic, or should we stop the program to do this?)
• Confirm SHMS/HMS momentum settings
• Set target to Longitudinal/180
  • Do we want to attempt flip to Longitudinal/0 during 3He elastics?

SHMS/HMS scintillator bars settings for He3 Elastic and QE runs

SHMS Paddle Configuration Optimized for He3 Elastic Measurement (8.5deg, -2.12860 GeV/c)

(From first_epics_HV.results https://logbooks.jlab.org/entry/3762329)

• Turn OFF all 1x paddles ((both sides: '+' and '-') EXCEPT 07, 08
• Turn OFF all 2x paddles ((both sides: '+' and '-') EXCEPT 07, 08, 09
  • Only this set of s1x and s2x channels should be ON

   s1x07+(L) s1x07-(R)
   s1x08+(L) s1x08-(R)
   
   s2x07+(L)  s2x07-(R)
   s2x08+(L)  s2x08-(R)
   s2x09+(L)  s2x09-(R)

• Keep all y paddles ON (unchanged)

HMS Paddle Optimization for He3 QE Measurement

• Turn OFF paddles 01 through 06 in h1x (both sides: '+' and '-')
• Turn OFF paddles 01 through 06 in h2x (both sides: '+' and '-')
• Only this set of HMS h1x and h2x paddles should be ON

    h1x07(+) through h1x16(+)
    h1x07(-) through h1x16(-)
    
    h2x07(+) through h2x16(+)
    h2x07(-) through h2x16(-)

• Keep all y paddles ON (unchanged)

HMS Paddle Config Optimized for He3 Elastic Measurement (11.7deg, -2.08234 GeV/c)

NOTE: These are a little more restrictive (more bars off); probably want to start with the above looser setting and then fine-tune (From first_epics_HV.results https://logbooks.jlab.org/entry/3762316)

• Turn OFF paddles 01 through 09 in h1x (both sides: '+' and '-')
• Turn OFF paddles 01 through 09 in h2x (both sides: '+' and '-')
• Only this set of HMS h1x and h2x paddles should be ON

    h1x10(+) through h1x16(+)
    h1x10(-) through h1x16(-)
    
    h2x10(+) through h2x16(+)
    h2x10(-) through h2x16(-)

• Keep all y paddles ON (unchanged)
• The HMS_all HV GUI after this action should be consistent with the A1n settings at https://logbooks.jlab.org/entry/3762307

A1n paddle studies for 3He elastics in SHMS, and QE in HMS

• For reference
  • SHMS (elastic) [3], [4]
  • HMS (QE) [5]

Run Plan for 1-pass

• Detailed plans heavily lean on excellent notes from A1n period

  • https://hallcweb.jlab.org/wiki/index.php/1-pass_calibration_for_A1n_(Jan_2020)
  • https://hallcweb.jlab.org/wiki/index.php/1-pass_calibration_for_A1n

Beam checkout

• Please refer to Beam and Raster Checkout for A1n/d2n (Long Procedure).

Moller Measurement (4--8 hours; Cancelled)

Consensus is to skip the Moller at 1-pass.

• Notes from Dave Gaskell

If we don't change the Wien angle for 1 pass running, Hall C should
receive 97.5% of maximum polarization (which is about 87.5% now, so Hall
C would get 85.3%).

At 1 pass and close to maximum polarization, we are very insensitive to
absolute beam energy and Wien angle.  Even incorporating a 3 degree
uncertainty in the Wien angle would only change the polarization about
1.3%. Few MeV differences in the beam energy, much less.

Anyway - I don't think there's much risk in skipping the 1 pass Moller
measurement in Hall C.  A super-conservative estimate of the
polarization uncertainty would be 4%. Conservative: 3%.

• Beam parameters to check at 1-pass:

    Photocathode QE         0.45280     (qe_hallc; nominal, should be above 0.30)
    Wien Angle:horizontal  -29.6402     (HWienAngle;  should NOT change)
    Beam energy             2179.7 MeV  (HALLC:p; nominal value is 2183 MeV)

Beam Energy Measurement (1 hour)

• Accelerator driven process -- will happen following initial beam checkout into the Hall
• Would be recommended, since it is a sensitive input to the beam polarization that Hall C receives

Reference Cell Hydrogen (H2) Cross Section (1--2 hours)

 Goals 
 - To measure hydrogen elastic cross section as a cross check of data quality
 - To measure backgrounds from glass cell and beamline windows (Reference-VAC)

 Setup
 - Beam Current: up to 30uA and DAQ rate-limited, raster always ON (4mm diameter)
 - Target:       Reference Cell: vacuum and filled with H2 to 135 psig
 - Detectors:    All scintillator bars on

 Spectrometer Setup (with HMS 11.7 deg, SHMS 8.5 deg)
 - HMS setting: 11.7 deg, -2.08234 GeV/c (electron QE)  -- Jan 3He elastic settings
 - SHMS setting: 8.5 deg, -2.12860 GeV/c (electron QE setting, but focus on 3He elastic events) -- Jan 3He elastic settings

 Procedure
 - Set spectrometers at the required settings, target at the Reference Cell position;
 - Evacuate Reference Cell (to vacuum), record the pressure reading in the Start_Run entries.
 - Ask MCC for 10uA raster ON (4mm dia), check rates and prescale factors
   (Save PS file if changed). Goal is to reach (3.5-4)kHz DAQ rate on both HMS
   and SHMS. If rates too low, increase the beam current but do not exceed
   30uA. If rates too high, prescale it down and do NOT drop current below
   10uA.
 - Take one 20-minute run, make sure there are no less than 10,000 events for each of HMS and SHMS.
 - Record the pressure in End_Run entries. 

 - Fill Reference Cell to 135 psig of hydrogen gas;
 - Keep beam current the same as the above Empty Cell run, check rates and
   prescale factors (Save PS file if changed). Goal is to reach (3.5-4)kHz DAQ
   rate on both HMS and SHMS. If rates too low, increase the beam current but
   do not exceed 30uA. If rates too high, prescale it down and do NOT drop
   current below 10uA.
 - Take one 20-minute run, apply ztar and W cut and make sure H2 elastic
   events from the H2 gas are no less than 10,000 for each of HMS and SHMS.
 - Record the pressure reading in the Start_Run and End_Run entries.

 Things to watch online
 - Ensure all scintillator bars are ON
 - For 10atm H2 filled cell, apply ytar or ztar cuts to isolate events
   scattered from H2 gas (We do not want events from the glass windows!), and
   apply W cuts to select only H2 elastic. Note the elastic peak is not at
   dp=0 because the spectrometers are set at 3He elastic. 
 - Run online script to ensure we collect no less than 10,000 H2 elastic (with
   ytar or ztar and W cuts) for each of HMS and SHMS

3He Reference Cell Runs (N2 and 3He Pressure Curves, False Asymmetries) (5hrs ideal, 3 hrs min)

 Goals 
 - For empty cell, to determine window background for elastic setting
 - For N2, need 5 points at 0.5(*), 1.0, 2, 4 and 8 atm, 10,000 N2 elastic events for each pressure setting and each spectrometer.
   (*) sub-atmosphere may not be possible (gauge not accurate enough)
 - For 3He, need 6 points at 1, 2, 4, 6, 8 and 10 atm, 10,000 3He elastic events for each pressure setting and each spectrometer.
 - Reference cell must be filled with 3He last, and do NOT pump the 3He gas out!
 - Time: couple of hours assuming 50% beam efficiency

 Setup
 - Beam Current: 10-30uA, raster always ON (4mm diameter). Do not drop currents below 10uA.
 - Target:       Reference Cell, Empty, filled with N2, filled with 3He (last)
 - Detectors:    We will need to keep only 2 scintillator bars ON to take mostly 3He elastic and limit quasi-elastic scattering events. 
 - Use these settings: Scintillator Settings
   A1n notes: hclog 3756736, hclog 3760238
   - HMS Detectors: turn off paddles 1-6 on 1X plane and paddles 1-6 on 2X plane
   - SHMS Detectors: keep only paddles 7,8 of 1X plane, and paddles 7,8,9 of 2X ON, all others off;
   - SHMS (continued): Also suggest for 1Y keep only 7 on, all others off, although this will depends on how well the collimators works

 Spectrometer Setup (with HMS 11.7 deg, SHMS 8.5 deg)
 - HMS setting: 11.7 deg, -2.08234 GeV/c (electron QE)  -- Jan 3He elastic settings
 - SHMS setting: 8.5 deg, -2.12860 GeV/c (electron QE setting, but focus on 3He elastic events) -- Jan 3He elastic settings

 Procedure
 - Set spectrometers at the required settings, target at the Reference Cell position.
 - Make sure the correct scintillator bars are ON.
 - Start at for 10 uA raster ON (4mm dia), check trigger rates and PS factors.
   Ideally we would like to see (3.5-4)kHz DAQ rates. If rates are too high,
   use Prescaling (save PS file if changed). If rates are too low, increase
   beam current but do not exceed 30uA.  Ensure that the livetimes are >80%
   in each arm.

 Nitrogen Pressure Curve
 - Evacuate cell to vacuum and take one 20-minute run.
 - Fill the cell (slowly) to 380 Torr with N2, take one 20-minute run.  (NOTE: vacuum gauge is unreliable due to overpressure exposure.  Is this useful?)
 - Fill the cell (slowly) to 1 psig, take one 20-minute run.
 - Fill the cell to 15 psig, take one 20-minute run.
 - Fill the cell to 45 psig, take one 20-minute run.
 - Fill the cell to 75 psig, take one 20-minute run.
 - Fill the cell to 105 psig, take two 45-min runs and flip the IHWP in between

 He3 Pressure Curve
 - Evacuate cell to vacuum and take one 20-minute run.
 - Fill the cell (slowly) to 380 Torr with He3, take one 20-minute run. (NOTE: vacuum gauge is unreliable due to overpressure exposure.  Is this useful?)
 - Fill the cell (slowly) to 1 psig, take one 20-minute run.
 - Fill the cell to 15 psig, take one 20-minute run.
 - Fill the cell to 45 psig, take one 20-minute run.
 - Fill the cell to 75 psig, take one 20-minute run.
 - Fill the cell to 105 psig, take one 20-minute run.
 - Fill the cell to 135 psig, take two 45-min runs and flip the IHWP in between

 - Important: After these runs are completed, do NOT pump out the 3He gas!

 Things to watch for
 - These reference cell runs must be taken with exactly the same spectrometer and scintillator settings as polarized 3He elastic asymmetry runs (see next).
 - Beam current should not be below 10uA (BCM accuracy) and should not be above 30uA (glass cell safety).
 - For each gas pressure setting (except for empty cells), need 10,000 events from gas alone (apply ztar cuts) for each of HMS and SHMS.

Polarized 3He Cell Density Measurement (1 hour plus time for setup)

 Goals 
 - To determine 3He and N2 density in cell Tommy
 
 Setup
 - Beam Current: 10uA, raster always ON (4mm diameter)
 - Target:      Polarized 3He Cell "Tommy", polarized in 180 deg.

 Spectrometer Setup
 - HMS setting: 11.7 deg, -2.1483 GeV/c (electron 3He elastic) for density of "Tommy".
 - SHMS setting: 8.5 deg, -2.1286 GeV/c (electron QE) for collimator check and asymmetry. 
 - SHMS Detectors: follow QE/el measurement setup below.
   -  HMS Detectors: turn off paddles 1-6 on 1X plane and paddles 1-6 on 2X plane
   - SHMS Detectors: keep only paddles 7,8 of 1X plane, and paddles 7,8,9 of 2X ON, all others off;
   - SHMS (continued): Also suggest for 1Y keep only 7 on, all others off, although this will depends on how well the collimators works
   - See Scintillator Settings

 Procedure
 - Set spectrometers at the required settings, target at the Polarized 3He Cell position;
 - Check that scintillator bars in HMS and SHMS are as specified above.
 - Ask MCC for 10 uA raster ON (4mm dia). Adjust prescale factor to limit the DAQ rate to 3.5-4kHz. 
   (Do NOT drop below 10uA. If rates are low, increase beam current but do not exceed 30 uA.)
 - Take two 30-min runs at this setting. (see below)

 Things to watch for
 - We need at least 10k events each from 3He elastic and N2 elastic peaks.
 - Run Chao's script to pull out # of events for 3He elastic and N2 elastic and post in hclog;
 - If we don't expect to achieve 10k events within one hour, contact RC.
 - For SHMS, post ytar(ztar) histogram in hclog. This shows effects of the new collimator.
 - Chao will run analysis remotely to extract 3He elastic fraction on SHMS.

Polarized 3He Runs, 3He elastic and QE longitudinal Asymmetries (12--16 hours)

 Goals 
 - To measure physics longitudinal asymmetry of 3He elastic (on SHMS) and QE (on HMS) scattering. 
 - If precision is high, this cross checks PbPt from Moller and Target Polarimetry. 
 - If precision is low, at the minimum we should determine the sign of asymmetries.
 - Experts must watch EDTM rate (Brad).

 Setup
 - Beam Current: 5-30uA, raster always ON (4mm diameter)
 - Target:      Polarized 3He Cell
 - Target spin direction: 180 deg
 - See Target Field Runplan for coil currents settings.
 - Time: total 12--16 hours of data taking, flip beam IHWP every 4 hours. Do
   target NMR every 4 hours (ask TO), but always before and after the full data taking.

 Spectrometer Setup (with HMS 11.7 deg, SHMS 8.5 deg)
 - HMS setting: 11.7 deg, -2.08234 GeV/c (electron QE)  -- January setting
 - SHMS setting: 8.5 deg, -2.12860 GeV/c (electron QE setting, but focus on 3He elastic events) -- January setting

 - Use these settings: Scintillator Settings
   A1n notes: hclog 3756736, hclog 3760238
   - HMS Detectors: turn off paddles 1-6 (or 1-9) on 1X plane and paddles 1-6 (or 1-9) on 2X plane
   - SHMS Detectors: keep only paddles 7,8 of 1X plane, and paddles 7,8,9 of 2X ON, all others off;
   - SHMS (continued): Also suggest for 1Y keep only 7 on, all others off, although this will depends on how well the collimators works

 Procedure
 - Set target at the Polarized 3He Cell position, spin 180 deg.

 - Perform one full set of polarimetry (NMR, EPR if possible) measurements before taking data.
 - Ask MCC for 10 uA raster ON (4mm dia), check trigger rates. Goal is to reach (3.5-4)kHz DAQ rates.
 - If rates too high, adjust PS factors (save PS file if changed!) and/or drop beam current but do not go below 5uA.
 - If rates too low (unlikely), increase beam current but do not exceed 30uA. 

 - Perform NMR every 4--5 hours

 - Start with all bars ON
 - Target is set to Longitudinal/180
 - Take 1 60-minute run (assuming 50% beam efficiency) (ALL BARS ON)
   - 30 minutes in, start analysis and verify above paddle settings are optimal

 - Configure HMS scintillator bar status the same as suggested above
 - Configure SHMS scintillator bar status the same as suggested above
 - Take 3 60-minute run (assuming 50% beam efficiency)
 
 - Call MCC and ask beam IHWP to be inserted (or taken out). Need to inform other halls prior to the switch.
 - Take 4 60-minute runs (assuming 50% beam efficiency).

 - Call MCC and ask beam IHWP to be inserted (or taken out). Need to inform other halls prior to the switch.
 - Take 2 60-minute runs (assuming 50% beam efficiency).
  
 - Rotate target to Longitudinal/0
 - Turn all bars ON
 - Take 1 60-minute run (assuming 50% beam efficiency) (ALL BARS ON)
 - Configure HMS scintillator bar status the same as suggested above
 - Configure SHMS scintillator bar status the same as suggested above
 - Take 3 60-minute run (assuming 50% beam efficiency)

 Things to watch online
 - Ensure the correct scintillator bars are on (We need 3He elastic events in SHMS and QE events in HMS)
 - Apply z cuts to isolate events scattered from 3He gas (We do not want events from the glass windows!)
 - Apply W or dp cuts to isolate 3He elastic (SHMS) or QE(HMS) events from others.
 - For HMS, run online script to ensure we see physics asymmetry. Plot asymmetry as function of nu (=E-E'). 
 - For SHMS, run online script to ensure we see physics asymmetry. Plot asymmetry as function of W(3He). 

 Predictions
 - QE asymmetry (HMS) predictions are given in hclog 3759756. 
 - Elastic 3He asymmetry (SHMS) is predicted to be 2.5% on SHMS, with Pb=0.8, Pt=0.5 and fN2=0.9 gives Ameas=0.9%.
 - Important: would like to have more than 6% of the full rate on SHMS to come from 3He elastic.

Polarized 3He Delta Transverse Asymmetry (4--8hr)

 Goals 
 - To determine the sign of transverse asymmetry of Delta resonance on HMS and SHMS.
 - On SHMS we will also take QE events which help to determine sign of transverse asymmetry.
 - Experts must watch EDTM rate (Brad or Sylvester)

 Setup
 - Beam Current: 5-30uA, raster always ON (4mm diameter)
 - Beam IHWP:    should be switched half-way
 - Target:       Polarized 3He Cell
 - Detectors:    All scintillator bars ON.
 - Parity check: Inform Hall A to make sure they set the Qasym feedback cutoff at 2uA.
 - 
 Spectrometer Setup (with HMS 11.7, SHMS 8.5 deg)
 - HMS setting:  11.7 deg, -1.75830 GeV/c (electron W=1.232)
 - SHMS setting:  8.5 deg, -1.79736 GeV/c (electron W=1.232)

 Pol 3He Target Setup (TO and Target Expert)
 - Target spin direction: pointing 270
 - Ensure correction coils are set properly

 Procedure
 - Set target at Polarized 3He Cell position, spin pointing either beam-left or beam-right.
 - Check and make sure all scintillator HVs are ON (both HMS and SHMS).
 - Perform one set of polarimetry (NMR, EPR if possible) measurements before taking data.
 - Ask for 5uA raster ON, check rates and set prescale factors (Save them if changed!). 
 - Goal is (3.5-4)kHz DAQ rates on both HMS, SHMS. 
 - If rates too low (unlikely), can increase current to reach the desired rates but do not exceed 30uA.

 - If we have 4 hours of beam time:

 - Take two 60-minute (beam ON at least 30 min each) runs.
 - Switch beam IHWP position (need to inform other halls in advance). Either from IN to OUT or from OUT to IN.
 - Take two 60-minute (beam ON at least 30 min each) runs.
 - Perform one set of polarimetry (NMR, EPR if possible) measurements.

 - If we have 8 hours of beam time:

 - Take four 60-minute (beam ON at least 30 min each) runs.
 - Perform one NMR measurement. Confirm target polarization
 - Switch beam IHWP position (need to inform other halls in advance). Either from IN to OUT or from OUT to IN.
 - Take four 60-minute (beam ON at least 30 min each) runs.
 - Perform one set of polarimetry (NMR, EPR if possible) measurements.

 Things to watch online
 - Apply y or z cuts to isolate events scattered from 3He gas.
 - Apply 1.1<W<1.35 GeV cut to isolate the Delta resonance.
 - Run online script to ensure we see physics asymmetry. Plot asym vs. W and nu. 
 - HMS and SHMS should see opposite signs of asymmetries (but not the same magnitudes). 

 - Expected asymmetries for Delta(1232): Ameas=0.67% at 11.7deg and 0.46% at 8.5 deg if Pt=50%, Pb=85%, N2 dilution 0.92.
 - Expected asymmetries for QE are given in hclog 3759756 (ignore Aperp2,
   SHMS will see Aperp always, up to a sign)
 - Expected rate: 5kHz at 1uA, about 10% (5% w/o collimators) would be
   Delta(1232) from 3He gas for HMS (SHMS), see hclog 3758839 analysis of 11.7
   deg data taken previously.
 - Counts needed to reach 10% on Ameas relative: 2.2M on HMS or 4.7M on SHMS.
   If Pt below 50%, scale up by (50%/Pt)^2.
 - Expected time to reach 10% on Ameas relative: 1.6 pac hours for HMS, 5.6
   PAC hours for SHMS with all paddles on and w/o collimators.  Adding target
   collimators on the SHMS side will help significantly).

Polarized 3He Elastic Longitudinal Asymmetry (until end of 1-pass running)

3He Asyms for 2.18 GeV/c (S. Barcus, S. Li)

• Continue with the Pol He3 Elastic group's run plan and continue stepping the SHMS out in angle) until we run out of beam time.

  • Rotate target back to 180deg
  • SHMS set to 11.0 deg to start, -2.08234 GeV/c (? Confirm)
  • HMS will rotate to 18.5 deg, -2.12860 GeV/c (? Confirm) and park there for remaining 3He Elastic Asym running

• Settings to be confirmed by Shujie, Scott

• new runplan (0918) TBD

• Note: These values are all estimates. Optimize current and prescale values (using the el_clean trigger ps3) to produce a data rate of ~4 kHz!

 Goals 
 - To measure physics longitudinal asymmetry of 3He elastic scattering to (2-3)% relative, cross check PbPt from Moller and Target Polarimetry

 Setup
 - Beam Current: 10-30uA, raster always ON (4mm diameter)
 - Target:      Polarized 3He Cell, Reference Cell
 - Target spin direction: 180deg only
 - See Target Field Runplan for coil currents settings.
 - Detectors:    We will need to keep only a few scintillator bars ON to accept 3He elastic and limit quasi-elastic scattering events. 
   - HMS Detectors: turn off paddles 1-6 on 1X plane and paddles 1-6 on 2X plane
   - SHMS Detectors: keep only paddles 7,8 of 1X plane, and paddles 7,8,9 of 2X ON, all others off;
   See Scintillator Settings
 - Parity check: Inform Hall A prior to taking data to make sure they set the charge asymmetry feedback cutoff at 2uA.
 - Time: total 8 hours of data taking with even split between IHWP settings
   Full target polarimetry measurements at the start and the end, plus pNMR
   (pulsed NMR) only every two hours or after each target spin flip.

 Procedure
 - Verify the correct Scintillator bars are ON.
   - Scintillator Bar Settings
 - Move target to Polarized 3He Cell position, spin polarization at 180 deg.
 - Perform one full set of NMR, (EPR?), pNMR polarimetry measurements before taking data, and every 4 hours thereafter
 - Set SHMS and SHMS DAQs to use EL_clean (T3) triggers unless unprescaled T1 rates are < 3.5 kHz
 - Ask MCC for 10uA raster ON (4mm dia), check trigger rates. Goal is to reach
   3.5kHz--4kHz DAQ rates. If rates too high, adjust PS factors (save PS file if
   changed!). If rates too low (unlikely), increase beam current but do not
   exceed 30uA.

 - Want at least 2--4 hours of beam on target for inital(8.5 deg) point; flip IHWP at half-way mark

 Things to watch online
 - Ensure the correct scintillator bars are on (We need 3He elastic events!)
 - Apply z cuts to isolate events scattered from 3He gas (We do not want events from the glass windows!)
 - Apply W or dp cuts to isolate 3He elastic events from others.
 - Run online script to ensure we see physics asymmetry. HMS and SHMS should
   see the same asymmetry. Asymmetry should flip sign with beam IHWP switch
   and target spin flip.

 - Expected asymmetries (3He elastic only): Aphys=5.0% Ameas~2% at 11.7 deg, or Aphys=5.8% Ameas=2.3% at 12.5 deg, if using Pt=50%, Pb=85%, N2 dilution 0.92.
 - Expected uncertainties dA/A=2% (goal) or 3% (minimum).

Important Scripts

• Elastic Electron Count Script:
  • Location: /home/cdaq/polhe3/production/hallc_online/analysis/elastic/el_asym_(s)hms.cxx
  • Description: These scripts count the number of elastic electrons in a data run after applying various cuts.
  • Usage: To use these scripts with the correct relative paths they must be executed from the ~/polhe3/production/hallc_online directory. They can be executed as 'root -b -q "analysis/elastic/el_asym_shms.cxx(11091)"'.
  • Output: The analysis plots can be found in ~/polhe3/production/hallc_replay/MON_OUTPUT/ANALYSIS_HISTOS/run#_analyzed/.
• Elastic Asymmetry Script:
  • Location: /home/cdaq/polhe3/production/hallc_online/analysis/elastic/asym_elastic.py
  • Description: This script will calculate the elastic asymmetry for runs listed in /home/cdaq/polhe3/production/hallc_online/database/(S)HMS_run_table.csv. The momentum and angle arguments will display only runs with settings near those given. The elastic counts used for this calculation come from calling the el_asym_(s)hms.cxx scripts mentioned above. Acceptance cuts for elastic electrons can be changed in those scripts.
  • Output: The plot of the asymmetries is written to ~/polhe3/production/hallc_online/progress/asym_elastic_(s)hms.png.
    • Usage: 'python3 asym_elastic.py SHMS -p 2.17 -a 8.5 -t 0.1 --estimate=0.026 --factor-qe=0.80 --date-start=2020-01-12'

Positional Arguments:

arm Spectrometer Arm (HMS or SHMS)

Optional Arguments:

-h, --help show this help message and exit

-p MOMENTUM momentum setting (GeV)

-a ANGLE angle setting (degree)

-t TOLERANCE absolute tolerance for settings

--date-start START start date

--date-end END end date

--counts-min CMIN minimum event counts for valid elastic runs

--estimate ESTIMATE estimated asymmetry for this setting (without any corrections)

--factor-qe F_QE dilution factor from Quasi-Elastic asymmetries

--run-script run count script if output does not exist

• Paddle Optimization Script:
  • Location: /home/cdaq/polhe3/production/hallc_online/analysis/hodo/draw_paddles_(s)hms.cxx
  • Usage: From /home/cdaq/polhe3/production/hallc_online/ execute 'root -b -q "analysis/hodo/draw_paddles_shms.cxx(9788)"'.
  • Output: The analysis plots can be found in ~/polhe3/production/hallc_online/paddle_plots/.

A1n 1-pass running notes

• https://hallcweb.jlab.org/wiki/index.php/1-pass_calibration_for_A1n_(Jan_2020)
• https://hallcweb.jlab.org/wiki/index.php/1-pass_calibration_for_A1n
• Elastic Run Summaries from A1n period: SHMS, HMS

POST-run Calibrations/Measurements

NOTE: We'll need RadCon support and probably Survey and Alignment for several parts.

Misc Items

• Hall is expected to go to Restricted Access around 11am--noon on Monday.

  • EPR photodiode replacement tentatively planned for Monday after lunch.

• NOTE

  SHMS will be 'stuck' at last angle we reach during He3-Elastic program on Monday (> 8.5 degrees)

  • Will need Techs and Steve/Amy to rotate SHMS back to 8.5 degrees on Monday when RadCon Survey is completed and we are in Restricted

• HCList(s) is here

  http://devweb.acc.jlab.org/CSUEApps/hclist/task/1818

• Establish a plan to keep the HB magnet on without people in the CH (Brad)

  • Got the go-ahead from Thia.
  • Discussed leaving Hall in Laser Controlled Access overnight (confirm this; maybe not worthwhile idea.. we do want to have others be able to enter the Hall in an emergency)
  • I've put an alarm on a number of critical PVs and system will send Text message alerts if they go out of bounds (trip, etc)
    • PV list (for now): HB current, LHe level, Itrue_diff Magnet Logger (Munin)

• Target calibrations will likely run through to Monday 28th

  • Target group is meeting at 1:30pm on Monday to discuss plans (Bluejeans)
  • Talk to RadCon and S&A about schedule

• Task requiring Tech Support

  • Crane work for the Compass optics table installation/removal

• Unser Wire calibration(?) (Mack?)

Survey Work

• Survey the Collimator positions before removal

• Compass measurement initial setup of the table/compass and to survey the points on the screen afterwards Media:Compass_Mapping_Procedure.pdf

  • Pre-job walkthrough with Chris Gould on Thursday 24th; Survey work could happen on Monday 28th (Will have to confirm and update based on target calibration progress)

• Pointing surveys for SHMS/HMS

  • Not sure what pointing surveys we have already.. Hall C Data S&A Transmittals isn't very up-to-date
  • Mark Jones' Github survey repo: https://github.com/MarkKJones/fall2017-plans/tree/master/Surveys
    • HMS: 40, 25, 15; SHMS 25, 15;
  • Mark Jones' Github 'A1n Pointing Scan': https://github.com/MarkKJones/shms_optics_a1n/tree/master/SHMS_POINTING_SCAN
  • Holly made a summary on the DocDB Mis-pointings of the HMS and SHMS
  • Survey reports from Nov 2019 (needs a permanent location)
    • HMS: 12.5, 30 ; SHMS: 12.5, 30
  • Our full set of angles for d2n/a1n are
    • HMS: Needed: 11.7, 13.5, 16.4, 20.0 Surveys done: 12,5, 30.0
    • SHMS: Needed: 8.5, 11.0, 14.5, 18.0, Surveys done: 12.5, 30.0
  • S&A likely won't be able to support pointing measurements until October

Remaining Target calibrations

Done:  See calibration spreadsheet below

• Junhao set up a Target Calibration Spreadsheet
• Tentative Target calibrations/testings for next week (JP) (Updated 2020-09-20 3pm)

 A. Monday-Tuesday
 - starting at 7 am on Monday when data taking ends:
 Tasks 1-5 will be Arun (7-8 am)/Murchhana (after 8 am)/Mingyu for PNMR)
 1) Move SHMS to 18 degrees, HB to 5.6 GeV/c. Keep target at longitudinal
    polarization 0 degree, oven at 208 degrees. Set the correction coils for
    this configuration. Move to pick-up position.
 2) After conditions stabilize, do NMR.
 3) Do PNMR, set frequency properly. DO PNMR/NMR calibration.
 4) Set convection heater to 9 V. Wait for condition stable, do PNMR/NMR.
 5) wait for ~3 hours, (before target enclosure opening for EPR
    photo-diode replacement), do PNMR/NMR. Change convection back to 7V.

 Task 6 (Junhao/JP)
 6) Replace EPR photo diode
      i) turn off lasers, Lockout laser fibers
      ii) with RADCON support, open target enclosure,
      iii) replace EPR photo-diode
      iv)) close target enclosure
      v) unlock laser fibers and turn on longitudinal lasers

 Task 7 Brad/Amy, Hall C techs.
 7) Move spectrometer to 8.5 degrees. Set HB to 2.1 GeV/c

 Task 8-19, Murchhana/Mingyu/Junhao
 8) EPR calibration for 0 degree
 9) Temperature test
 10) AFP loss measurement
 11) PNMR loss measurement
 12) Rotate to 180 degree
 13) Spin up at 180 degree
 13) EPR test
 14) Temperature test
 15) AFP loss measurement
 16) PNMR loss measurement
 17) Rotate to 270 degree, set QWPs
 18) Rotate SHMS to 11 degree, set HB to 7.5 GeV/c, set correction coils
 19) Spin up at 270 degree

 Wednesday: (Junhao/Mingyu/all)
 1) EPR at 270
 2) Temperature test at 270
 3) AFP loss at 270
 4) PNMR loss test
 5) Rotate to 90 degree
 6) Temperature test at 90
 7) AFP loss at 90
 8) PNMR study?
 9) Cross calibration between 90 and 180, ending at 180
 11) Convection speed study at 7V
 12) Rotate to 270 and Spin up at 270

 Thursday: (Junhao/Mingyu/all)
 1) Rotate SHMS to 18 degree, HB to 5.6 GeV/c
 2) AFP loss at 90
 3) EPR at 90
 4) ladder position test NMR/PNMR
 5) PNMR study?
 6) Study field effect on NMR
 7) Cross calibration between 90 and 0, ending at 0
 8) Convection speed study at 9 V
 9) Rotate to 90 and Spin up at 90
 10) Hot-spin down overnight

 Friday-Sunday: (all)
 1) Study possible reasons for polarization difference in different
 directions, different conditions?
 2) Study possible reasons for not reaching optimal max?
 3) Cold spin-down

Compass Field Measurements

Done: https://logbooks.jlab.org/entry/3853995

• Compass measurements (should do as much as possible by Thurs Sep 24 so Murchhana can support)
  • Basic procedure: Media:Compass_Mapping_Procedure.pdf
  • Murchhana will update/create a procedure that minimizes number of Survey and Alignment setups (multiple screens, etc?)
  • Make a list of needed compass measurements (Murchhana)

Regular Field Measurements

• Should begin Oct 6 or 7
• Field measurement plan: Field Mapping Plan, Fall 2020

• Preparations:
  • Locate field probes, support jigs, etc.