Proton Calorimetry/Experimental Runs/2018/Oct25-6: Difference between revisions

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# Aligned calorimeter to tracker, with centre of mylar window and tracker window aligned.
# Aligned calorimeter to tracker, with centre of mylar window and tracker window aligned.
# Performed beam test, details provided below.
# Performed beam test, details provided below.
# Was found that the tracker was not completely set centre to the beam.
# Error in data taking: Trigger trace was recorded instead of PMT trace.


== Beam Tests ==
== Beam Tests ==

Revision as of 08:50, 26 October 2018

Beam tests of the single module with PRaVDA Silicon strip tracker with trigger pulse output at the Birmingham Cyclotron with a 36 MeV beam.

Equipment List

Item Notes
Single Module Scintillator Block 3cm x 3cm x 5cm standard scintillator block. Optical gel required to couple Scintillator to PMT
Photomultiplier Tube Hamamatsu R13089 2"
Portable Enclosure Modified Peli 1510 Waterproof Wheeled Equipment Case.

230 x 555 x 350mm
Features mount for scintillator and PMT, opening for beam, and ports for SHV, BNC, and SMA cables.
Mylar window with Al support mounted to internal face: approximately light-tight.
BNC output from case connected to SMA splitter.

LeCroy HDO6104 Oscilloscope Records PMT output, connected via SMA-BNC conversion.
Caen DT5751 Digitiser Records PMT output, connected via SMA-MCX conversion. Used channel 3.
DAQ Laptop Controls Caen HV supply; records data from Caen digitiser.
Caen NDT1470 HV Supply Supplies HV to PMT
PRaVDA Strip Tracker PRaVDA Unit A, 3x150um Si strip sensors with 90.4um strip pitch.
Firmware version update to yield square pulse out when 2 or 3 layers have a strip over threshold per read out cycle
Control Laptop x 3 Two used for Remote Desktop control of LeCroy Oscilloscope and DAQ Laptop. Third used for taking down notes.
Ethernet Switcher Set in experiment room and connected LeCroy Oscilloscope and DAQ laptop. Output sent to control room Network Hub.
Network Hub Set in control room to take output from ethernet switcher. Control laptops connected via ethernet or 5GHz WiFi.
Ethernet Cable x 3 To connect 1 control laptop, the LeCroy HDO6104 and DAQ Laptop to their respective network hubs.
Ethernet Cable To connect control Network Hub to Ethernet Switcher.
Male-to-Male SMA Cable Signal from enclosure port to Splitter
DC-4200 MHz Signal Splitter Splits SMA signal to two SMA signals – sent to Oscilloscope and Digitiser.
Male SMA to Male BNC cable Sends 1 output from splitter to Oscilloscope.
Male SMA to Male MCX cable Sends 1 output from splitter to Digitiser
USB Cable Caen HV unit to DAQ Laptop
Gloves For handling scintillator
Optical gel For coupling scintillator to PMT
Wipes For removing optical gel

Experiment List

28 MeV beam Scattering Foil in 2mm diameter collimator 10kHz rate ~= 160pA onto Transmission Chamber before 2mm collimation

  1. Bragg Peak Measurements
  2. Combined scope / digitizer measurements with pristine bragg peak, 100mV trigger threshold
  3. Combined scope / digitizer measurements with pristine bragg peak, varying trigger threshold
  4. Degrade beam energy and measure response with 1-6mm PMMA before calorimeter
  5. PRaVDA box with 2mm collimator, trigger from scope
  6. PRaVDA box with 2mm collimator for trigger output


36 MeV beam Scattering Foil in 2mm diameter collimator 10kHz rate ~= 160pA onto Transmission Chamber before 2mm collimation

  1. Bragg Peak Measurements
  2. Combined scope / digitizer measurements with pristine bragg peak, 100mV trigger threshold
  3. Combined scope / digitizer measurements with pristine bragg peak, varying trigger threshold
  4. Degrade beam energy and measure response with 1-6mm PMMA before calorimeter
  5. Offset 2mm collimator (by 6mm) for optimal trigger threshold
  6. Double 2mm collimator (12mm separated) for optimal trigger threshold
  7. PRaVDA box with 2mm collimator, trigger from scope
  8. PRaVDA box with 2mm collimator for trigger output
  9. Degrade beam with 1-6mm PMMA with tracker

Experiment Log

25/10/18

  1. Set up apparatus as described in equipment list.
  2. Beam experienced difficulties, delaying data collection.
  3. Tracker operates on a 26MHz clock, and a trigger is sent whenever 2/3 silicon layers in tracker record events in a timestamp. Trigger tests were conducted with noise, hence a random rate in tests below.
  4. Tested trigger output of Tracker into Oscilloscope: square wave of period ~15 ns with amplitude ~400 mV. Pulse example recorded on Oscilloscope disk in folder: SShaikh/Tracker Trigger
  5. Placed signal splitter for trigger to send to both Digitiser and Oscilloscope. Amplitude reduced to ~50%. Pulse example recorded on Oscilloscope disk in folder: SShaikh/Tracker Trigger (Split)
  6. Split trigger suspected too small for Digitiser (accepts trigger of order ~V), hence Digitiser set to self-trigger mode. Needs further testing.
  7. Aligned calorimeter to tracker, with centre of mylar window and tracker window aligned.
  8. Performed beam test, details provided below.
  9. Was found that the tracker was not completely set centre to the beam.
  10. Error in data taking: Trigger trace was recorded instead of PMT trace.

Beam Tests

Thursday 25th October

PMT Current at HV supply -900 V, beam off: 150 μA

28MeV beam. Scope triggered by tracker. Cyclotron issues meant short run (~90 mins). Test of tracker triggering/scope synchronisation.

Scope timebase: 20ns/div; trigger delay 80ns; C1 vertical scale 50mV/div.

Tracker data indicates beam horizontal offset of 12mm; vertical offset of 1.3mm.

Data stored in directory ProCal_Birm_25-10-18

Run Number High Voltage (V) Trigger Level (mV) Trigger Source Beam Current / Rate Collimator Filename Notes
00 -900 70, +ve Tracker (C2) 170pA/~10 kHz 2 mm centred run00_2mmCCol_160pA_TrackTrig First test of tracker/PMT synchronisation
01 -900 70, +ve Tracker (C2) 160pA/~10 kHz 2 mm centred run01_2mmCCol_160pA_tracktrig Also took Caen ADC data
02 -900 70, +ve Tracker (C2) 160pA/~10 kHz 2 mm centred run02_2mmCCol_160pA_tracktrig Caen ADC run 01 data also includes run 02 (long run)