ONLINE AND OFFLINE CALIBRATION TOOLS FOR PHYSICS TOF
ONLINE AND OFFLINE CALIBRATION TOOLS FOR PHYSICS TOF Meeting, 9 December 2009, CERN Chiara Zampolli for the ALICE-TOF
Outline The TOF Calibration Sources of uncertainty Operating status The online procedures The offline procedures Chiara Zampolli 9 th December 2009 2
Sources of Uncertainties and Operating Status
Sources of Uncertainty 1. TIME DELAYS: an equalization of the channels of the TDCs is necessary because of the delays introduced by the electronics (mainly cable lengths and pulse line lengths). 2. TIME SLEWING: time slewing is caused by the finite amount of charge necessary to trigger the discriminator charge fluctuations generate a time walk. Chiara Zampolli 9 th December 2009 4
Operating Status Apart from correcting for the time delays and the time slewing effects, during reconstruction also the operating status of each channel has to be taken into account Front-End: off/on Noise: noisy/not-noisy Pulser: ok/not-ok Chiara Zampolli 9 th December 2009 5
TOF Online Calibration Procedure
TOF Online Calibration TOF online calibration procedure is aimed at defining the status and at a first-order estimation of the delay in time measurement of each TOF channel. TOF online calibration is performed on three different sources: � PHYSICS runs � PULSER runs � NOISE runs Delay Procedures running in the DAQ Status with additional information concerning the Front. End: � every run Procedure running in the DCS Status Everything included in the ALICE online calibration framework Chiara Zampolli 9 th December 2009 7
TOF Online Calibration - Delays Determine the relative delays for each TOF channel using the t. TOF-texp spectra No delay, edge @ ~ 0 • t. TOF = time measured by TOF (T 0 subtracted!!) • texp = expected time of flight, from TOF geometry, assuming β = 1 and a straight line trajectory Sharp edge expected at the delay value from fastest particles (β ~ 1) Delay defined using the mean <t. TOF-texp> over ~ 320 ps (≈ 4 times σTOF) around the edge <t. TOF-texp> Chiara Zampolli 9 th December 2009 8
Dependence on the Number of Entries/Channel Uncertainty (RMS) on the time edge vs Number of Entries/Channel Fit to 1/ N Mean Value of the Time Edge vs Number of Entries/Channel (delay=0). Stable within 10 ps. Chiara Zampolli 9 th December 2009 9
Dependence on the Number of Events pp Runs, assuming 10 hits on TOF/MB event 4 hours fill, L 2 rate = 100 Hz Chiara Zampolli 9 th December 2009 10
TOF Offline Calibration Procedure
Offline Calibration Strategy An algorithm with the aim to calibrate the measured times taking into account at the same time the time slewing effect and the delays introduced by electronics (refined calibration) has been developed. To unfold the time spread due to the momentum spectra, to the particle types, and to the different track length, the algorithm is based on the comparison between the times of the reconstructed tracks (from track length and momentum measurements) and the measured times (t. EXP-t. TOF). The identity of the particle (needed to choose the proper t. EXP) is determined via a combinatorial algorithm. Chiara Zampolli 9 th December 2009 12
Offline Calibration Procedure Quality cut selection applied on the available tracks 5 th order polynomial fitting of the (texp – t. TOF) vs To. T distributions for the selected tracks channel by channel; Setting of the 6 parameters just obtained as the calibration parameters CALIBRATION Chiara Zampolli 9 th December 2009 13
Results obtained with 500 tracks from 2 MC Pb-Pb ev; time delay = 2 ns. Results from MC Adding time slewing and delays 1. Simulated, w/o effects σa = 92. 7 ps 2. Simulated, with effects σb = 111. 4 ps 3. Simulated, calibrated σc = 93. 2 ps calibration σcal = ~ 10 ps Chiara Zampolli 9 th December 2009 14
Dependence on the # of Selected Tracks The residual σcal depends on the number of selected tracks used in the calibration procedure. Given a certain number of tracks to be collected/TOF pad, the number of required events comes. Chiara Zampolli 9 th December 2009 15
Required Statistics The number of required events to collect sufficient statistics to calibrate all the ~ 160000 TOF channels is: Ntr = # tracks/pad to obtain a given σcal k = selected tracks “occupancy” ~ 250/160000 (250 = # selected tracks in an event) To obtain σcal ~ 15 ps (which is well within the TOF requirements), Ntr ~ 400. The number of necessary Pb-Pb events to be collected is O(3 x 105). Chiara Zampolli 9 th December 2009 16
Required Statistics – pp Runs The number of reconstructed tracks in a MB pp event is ~ 2. Due to the much cleaner environment in which reconstruction is carried out, the track selection criteria can be much looser, so that all the reco tracks are taken into account. For σcal ~ 35 ps, the number of necessary tracks per channel is ~ 150. Then, the number of required MB pp events is O(107). Chiara Zampolli 9 th December 2009 17
Summary and Conclusions TOF Online and Offline Calibration procedures defined and implemented since long time TOF Online and Offline Calibration procedures developed for collisions So far, calibration from cosmics used TOF Online and Offline calibration tools used to determine channel by channel: Operating Status of the channel: �Online Calibration always used Time Delay & Time Slewing relative to the channel: �TOF Online and Offline Calibration not to be used together: �Online Calibration to be used first �Offline Calibration to be used second switch between the two foreseen Chiara Zampolli 9 th December 2009 18
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