Difference between revisions of "Electron Detector"
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== Standard Running Procedure == | == Standard Running Procedure == | ||
| − | + | '''with the previous beam activity ongoing (parasitically)''' | |
* take a quick CODA run to check DAQ functionality | * take a quick CODA run to check DAQ functionality | ||
* check analyzer functionality | * check analyzer functionality | ||
| Line 11: | Line 11: | ||
** Normalized Compton Photon Rates (cComptPhotonRateNorm) | ** Normalized Compton Photon Rates (cComptPhotonRateNorm) | ||
| − | + | '''Request beam to be set through the chicane and verify the same''' | |
* Check Chicane view: on any cdaq machine type '''edmmonticello''', from the '''Monticello''' screen | * Check Chicane view: on any cdaq machine type '''edmmonticello''', from the '''Monticello''' screen | ||
** open '''Magnets''' -> '''Magnet Commander''' | ** open '''Magnets''' -> '''Magnet Commander''' | ||
| Line 21: | Line 21: | ||
* Check compton rates from the photon detector (typically 600 per uA per second) | * Check compton rates from the photon detector (typically 600 per uA per second) | ||
| − | + | '''Request beam to be taken off, for lowering the e-detector''' | |
* Lower the e-detector to a position in accordance with current run plan | * Lower the e-detector to a position in accordance with current run plan | ||
** Motion mechanism [[https://hallcweb.jlab.org/polwiki/index.php/E-Detector_Motion_System#Motion_Mechanism_GUI]] | ** Motion mechanism [[https://hallcweb.jlab.org/polwiki/index.php/E-Detector_Motion_System#Motion_Mechanism_GUI]] | ||
Revision as of 01:33, 26 November 2010
Standard Running Procedure
with the previous beam activity ongoing (parasitically)
- take a quick CODA run to check DAQ functionality
- check analyzer functionality
- from any cdaq machine, from the directory ~/compton execute StripTool edetectorEpics.stp . This pulls up the strip chart of some relevant epics variables for e-detector. If you are unable to locate this file, the following epics variables should be explicitly opened.
- 4 Hall-C Chicane BPMs
- 3P01A (IPM3P01A.XPOS , IPM3PO1A.YPOS)
- 3P02A (IPM3P02A.XPOS , IPM3PO2A.YPOS)
- 3P02B (IPM3P02B.XPOS , IPM3PO2B.YPOS)
- 3P03A (IPM3P03A.XPOS , IPM3PO3A.YPOS)
- Normalized Compton Photon Rates (cComptPhotonRateNorm)
- 4 Hall-C Chicane BPMs
Request beam to be set through the chicane and verify the same
- Check Chicane view: on any cdaq machine type edmmonticello, from the Monticello screen
- open Magnets -> Magnet Commander
- 3C -> Compton Combo
- In this Hall C Compton Control screen, the REQUESTED and ACTUAL current readbacks should be ~104 A
- open BPM -> BPM Overview
- open Absolute -> on the Hall C column from the left bottom of this screen
- BPM 3P01A, 3P02A, 3P02B and 3P03A should have finite non-zero read back
- open Magnets -> Magnet Commander
- Check compton rates from the photon detector (typically 600 per uA per second)
Request beam to be taken off, for lowering the e-detector
- Lower the e-detector to a position in accordance with current run plan
- Motion mechanism [[1]]
- begin with the program Go Home
- jog to the intended position
- Motion mechanism [[1]]
Run Plan
Previous (Nov 17)
- Form an external coincidence between strip #5 or 6 of all three planes.
- count it on a visual scaler. look at each of the 3 plane signals on a scope to determine a good coincidence window.[this setup is ready]
- record 1/3, 2/3 and 3/3 at 2.8, 2.0 and 1.2 cm from the beam, with and without beam. Collecting statistics for ~ 3-5 minutes
- Repeat above with the full DAQ. Again 1/3, 2/3 and 3/3 at same distances from the beam, with and without beam.
- Try a couple of different trigger coincidence widths in the 100 - 250 ns range.
- Take a few long runs with 2/3 and 3/3 trigger at 1.5 cm from the beam, with and without beam, with and without laser
Upcoming
Seek a beam time of 6.5 hrs. Following tasks to be accomplished:
- With laser turned off for this entire running period resolve the plane-4 HV ambiguity: (~ 1 hr)
- look at output from all 3 planes on the scope, triggering on 2-plane coin while turning on HV of only one plane at a time
- do this for plane-2 and plane-3 first
- finally turn on p4 (repeat for a few neighboring strips if needed)
- record scope shots triggered on coincidences
- look at output from all 3 planes on the scope, triggering on 2-plane coin while turning on HV of only one plane at a time
- with the DAQ, try to observe a shift in the strip pattern as the detector is lowered towards the beam. (~ 3.5 hrs)
- If the plane-4 ambiguity is resolved then use all 3 active planes for trigger decision
- If plane-4 is not resolved, turn off the HV input to "plane-1" as well as "plane-4", mask the plane-4 signals and use 2-plane triggers only with plane-2 & plane-3.
- take quick runs to check if smaller or higher cut on minimum width helps
- try to find a trade-off between unmasking the strips neighboring the closest active strip and noise rates
- take 30 min runs with 5 uA, 3 uA and 1 uA beam with the detector at a reasonably close position (say 1.6 cm from beam)
- Repeat in steps of 1 mm as the detector is moved closer to the beam (~ 3 steps should be sufficient)
- HV scan for plane 2 only (~2 hr)
- With the detector at the closest position, and a 3 uA beam scan the HV from 300 - 700V in steps of 100 V taking 10 min runs at each voltage
- use 2-plane trigger, check to see if the background is different with change in applied HV
- use a 1-plane trigger, check to see if the background is different with change in applied HV
- It might be useful to increase the cut on minimum width in order to look over the excessive noise in the case of single-plane trigger.
- With the detector at the closest position, and a 3 uA beam scan the HV from 300 - 700V in steps of 100 V taking 10 min runs at each voltage
Backout Procedure
- Turn OFF HV
- Retract the detector to position defined as Go Home
- Retract further to position defined as Garage
- make hclog entry to inform completion of the intended studies, with any quick conclusion which are obvious
- courtesy: Thanks to Dave Gaskell for the motivation to organize this information
