Scintillating Fibre Cosmic Ray Test Results

1. Scintillating FibreCosmic Ray Test Results Malcolm Ellis Imperial College London Monday 29th March 2004

2. Fibre Tracker Measurements • Status at Abingdon Meeting • VLPC decoding • Trigger Timing • Reconstruction: • Pedestal and CMN • Clusters • Space Points • Tracking • Dead Channels • Track Residuals • Light Yield

3. Status at Abingdon • 3 Station tracker had been assembled (in only a few months) and data-taken at D0 test stand in Fermilab • First analysis of the data saw signals from the tracker, however there were question marks over the decoding of the data and less light seen than anticipated. • Initial estimates of efficiency and dead channel rates were consistent with expectations, however had large uncertainties...

4. VLPC Decoding • The tracker is read-out by one 1024 channel VLPC cassette, through eight 128 fibre D0 connectors. • Each of these is read out by a pair of multi chip modules (MCMs). • The ordering of the data in the output stream from the MCMs was originally incorrect. • This has been corrected, and two parallel approaches to describing the full decoding from electronics channel to station, plane and fibre numbers now agree completely.

5. Trigger Timing • There is a particular window during which the VLPCs are most sensitive to arriving photons. • A delay between the trigger and VLPC read-out needs to be adjusted in order to time the read-out with respect to the trigger such that the light arrives during this window. • Studies of light yield versus timing have shown that in 2003 this situation was not optimised. • The data taken in March 2004 has included a timing scan to optimise the read-out.

6. Gain Settings and Calibration • DAQ run with ramp trim set at two values: • 0x150 (most data) gives gain of ~5 ADC/PE • 0x350 (small amount) gives gain of ~14 ADC/PE • Calibration of gains for each channel determined from runs taken with LED. • Not had enough time to sort out channels with poor fits from 2003 data, so will only use 2004 data. • Mean gain is 5.3 ADC/PE with a spread of about 12%.

7. Pedestal and CMN • Pedestals are typically around 30 ADC counts. • Common noise per MCM (64 channels) creates a global shift of all 64 channels from event to event. • This CMN is subtracted event by event. • Resulting distribution shows pedestal at 0 (width 2.9 ADC) with signal above. • 3 times sigma of pedestal width is 1.95 PE.

8. Reconstruction - Clusters • Most tracks go through one group of seven fibres, and so a single electronic channel sees all the light. • A fraction go through the edges of two neighbouring groups, and so the light is shared between neighbouring channels • A cluster is built from one or two channels, each channel must have at least 1 PE and the sum must have at least 2 PE.

9. Space Points • Triplets (a hit in all 3 projections) are built in station B first. Clusters used in a triplet (or triplets) are not used in the next stage. • Duplets (pairs of clusters in two projections of a station) are built from all remaining combinations in all 3 stations. • Due to DAQ restriction (only 1 cassette means 1008 out of 1512 channels read-out), active area in 3 stations is not the full 30cm circle.

10. Tracking • All combinations of points are tested, and that with the best c2 is kept (assuming that the c2 is small enough). • 2003 data has 1670 tracks. • 2004 data taken so far has 8484 (0x150) and 1679 (0x350) tracks. • Space points in tracks are used to determine point resolution. • Light Yield determined by looking at distribution of light in clusters that are included in a track.

11. Our First Track:

12. Dead Channels • For each channel, determine the rate of hits above 4 PE on that channel. • Plot rate versus channel number and look for channels that are 0, or very low. • No channels with exactly 0 hits, however 1 with a very low rate, and another that is a little lower than its neighbours. • Worst case: 2 / 1008 = 0.2% • G4MICE assumption is 0.25%

13. Point Resolution • Take two points in a track, use these to determine expected position in third station. • Point resolution is residual width after extrapolation error is subtracted in quadrature. • Two options: • Interpolation (Stations A and C) • Extrapolation (Stations A and B or B and C)

15. Point Resolution • Subtracting extrapolation error from residual widths (RMS or sigma) gives point resolution (assuming all three X planes have the same resolution). • Resolution = 442 ± 4 (stat) ± 27 (syst) mm. • Depending on definition of the width of one channel (clusters complicate the issue slightly), expected resolution is between 424 and 465 mm. • Resolution measured in tracker agrees with expectations.

16. Light Yield • 7 planes contain different amounts of 3HF: • 2500 ppm (1 plane) • 3500 ppm (1 plane) • 5000 ppm (4 planes) • One plane has a mixed composition and is not used for this study. • Proposal assumed a light yield of 8 PE. • Due to non-linearity in gain at high signal, gaussian fit to most-probable peak.

17. 5000 ppm 3HF

18. 3500 ppm 3HF

19. 2500 ppm 3HF

20. Single Plane Efficiency • Efficiency calculated in Station B, one plane each of 2500, 3500 and 5000 ppm 3HF. • Track built from 6 other planes and extrapolated to plane under test. • Road-width varied from 2 to 50mm. • Systematic errors determined from variation with road-width and runs on different sets of data. • Algorithm will not over-estimate efficiency, but as a result may slightly under-estimate it.

21. Efficiency • Efficiency expected due to Poisson: • 8 PE: 98.62 % • 9 PE: 99.38 % • 10 PE: 99.72 % • Efficiency measured (0x150 data): • 5000 ppm 3HF: 97.45 ± 0.20 (stat.) ± 0.51 (syst.) • 3500 ppm 3HF: 98.80 ± 0.14 (stat.) ± 1.11 (syst.) • 2500 ppm 3HF: 99.26 ± 0.11 (stat.) ± 0.88 (syst.) • Efficiency measured (0x350 data): • 5000 ppm 3HF: 98.09 ± 0.39 (stat.) • 3500 ppm 3HF: 99.29 ± 0.25 (stat.) • 2500 ppm 3HF: 99.73 ± 0.16 (stat.)

22. Conclusions • Tracker performs at least as well as expected based on expectations from D0 and design: • Light Yield better than 8 PE • Single Plane efficiency consistent with light yield • Dead channel rate lower than G4MICE assumption • Point Resolution as expected from design • Performance currently being fed into G4MICE (see talk on Wednesday) • Only thing left is to build a couple of full trackers for MICE…