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Photon Transport Monte Carlo

Photon Transport Monte Carlo. Matthew Jones/Riei Ishiziki. Purdue University. Some results for specific track configurations Timing biases ignoring variation in pulse height Ideas for parameterization of these effects (physical model). November, 2004. Overview.

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Photon Transport Monte Carlo

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  1. Photon Transport Monte Carlo Matthew Jones/Riei Ishiziki Purdue University • Some results for specific track configurations • Timing biases ignoring variation in pulse height • Ideas for parameterization of these effects (physical model) November, 2004

  2. Overview • Methods previously described on Sept 27. • Applied to three configurations, all of which are currently treated as isochronous: • Cot() at constant z, • path length at constant z, cot(), •  at constant z, cot(). • All configurations result in large variations in pulse height. • Time measured at constant fraction of 5% of the total pulse height.

  3. 2 GeV/c muons at z=0 Path length varies by about p2 Variation in time is about §25 ps Smaller variation in T Variation with cot()

  4. 2 GeV/c muons at z=0, cot()=0 Significant variation of path length with ‘s’ Variation in time of about §25 ps Variation with path length s

  5. Variation with  • Muon momentum varied from 30 MeV to 300 MeV. • Factor of 10 variation in dE/dx with :

  6. This is approximately p>300 MeV/c for protons. Time variation is of the order of ns Time difference is essentially unbiased Variation in 

  7. Observations so far • Several effects introduce §25 ps variations in single channel timing measurements • Many are cancelled in T • Systematic effects would be enhanced for average time • Possible source of the correlations observed in the data

  8. “Physical” models • For a particular configuration (z, cos(), path length, , but not particle type), pulses will have the same average shape. • Amplitude determined by the Landau fluctuations in energy loss. • Light front due to ionization at a point in the bar has a z-dependent shape. • Light front due to path through the bar is the convolution of the point response.

  9. Point response function • Voltage pulse is V(t). • Discriminator fires when V(t) – V0 = 0. • ADC measures Q /stt+ t V() dt. • Q probably depends mainly on z. • Walk correction needs to be parameterized by Q/hQi.

  10. Next steps • Validate point response physical model: • Generate point response function with high statistics at several points in z • Convolute with various track configurations • Compare with full Monte Carlo • Treatment of walk correction: • Not necessary to fully validate ADC response model for testing point response hypothesis • Compare constant fraction with fixed threshold results

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