Electron Detector

Standard Running Procedure

with the previous beam activity ongoing (parasitically)

• Turn ON High Voltages to the e-detector
  • take a quick run to check DAQ functionality
  • check analyzer functionality
• from any cdaq machine, from the directory ~/compton open the strip chart by 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)

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
• 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

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 ~ 5hrs. Following is what is intended:

• Resolve the plane-4 HV ambiguity: (~ 0.5 hrs)
  • look at output from all 3 planes on the scope, turning on HV of only one plane at a time
    • do this for p2 and p3 first
    • finally turn on p4 (repeat for a few neighboring strips if needed)
    • record scope shots including coincidences.

• with the DAQ, try to observe a shift in the strip pattern as the detector is lowered towards the beam. (~ 3.5 hrs)
  • use 3 active planes if HV ambiguity is resolved, use 3-plane trigger if possible
  • use smaller min. width rejection if needed.
  • unmask the strips neighboring the closest active strip
  • take 30 min runs with 5 uA and 3 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)
  • a 30 min no beam run when the detector is at its closest proximity to beam.

• HV scan for plane 2 only (~1 hr)
  • With the detector at the closest position, and a 3 uA beam scan the HV from 350 - 700V in steps of 50 V taking short 5-10 min runs at each voltage

Backout Procedure

1. Turn OFF HV
2. Retract the detector to position defined as Go Home
3. Retract further to position defined as Garage
4. 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

Request beam according to the intended run plan

Diamond strip electron detector

Test Box

Shielded Flex Cables

Q-Weak Amplifier Discriminator

Low Voltage Power supply for QWAD

e-Detector Motion System

e-Detector Assembly