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On Noise Characterization Michel Lefebvre University of Victoria Physics and Astronomy 14 August 2003.

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Presentation on theme: "On Noise Characterization Michel Lefebvre University of Victoria Physics and Astronomy 14 August 2003."— Presentation transcript:

1 On Noise Characterization Michel Lefebvre University of Victoria Physics and Astronomy 14 August 2003

2 M. Lefebvre, 14 August 2003On Noise Characterization2 Noise Characterization A good characterization of the digital filtering noise is crucial to most analysis The digital filtering noise reduction factor depends on the layer and on  Strategy to estimate the digital filtering noise for each channel using only a given data run:  The pedrms are obtained from the first time sample the usual way;  For the channels with no signal in them (following some criteria), compute the noise/pedrms, where the noise is the result of a gaussian fit;  Obtain the average noise/pedrms ratio for a given layer and  ;  Interpolate to other channels (those considered to have signal in them) using the corresponding average noise/pedrms ratio;  This is implemented in TBRootAna as NoiseAlg.

3 M. Lefebvre, 14 August 2003On Noise Characterization3 Noise Characterization: HEC The digital filtering noise reduction factor depends on the layer and on  and ranges from 0.54 to 0.70  noise/pedrms  vs  noise vs  13188 is a muon run

4 M. Lefebvre, 14 August 2003On Noise Characterization4 Noise Characterization: EMEC The digital filtering noise reduction factor depends on the layer and on  and ranges from 0.46 to 0.77  noise/pedrms  vs  noise vs  13188 is a muon run

5 M. Lefebvre, 14 August 2003On Noise Characterization5 Occupancy Consider the occupancy of all cells for a given run, obtained using pedrms as a noise characterization occupancy computed using |signal| > 1pedrms expect channels with no signal to be at 31.7%. They are not! the occupancy distribution is broad because the noise/pedrms ratio varies over the calorimeters the number of entries in each plot is the number of connected readout channels for each detector 13188 is a muon run HEC EMEC a few dead channels

6 M. Lefebvre, 14 August 2003On Noise Characterization6 Noise Quality The quality of the digital filtering noise can be assessed by studying the occupancy of all cells for a given run occupancy computed using |signal| > 2  expect channels with no signal to be at 4.55%. They are! Their distribution is narrow channels with signal in them clearly have large occupancy (here only a few since this is a muon run) There are a few very noisy channels with non-gaussian noise (next slide) the number of entries in each plot is the number of connected readout channels for each detector 13188 is a muon run HEC EMEC a few dead channels

7 M. Lefebvre, 14 August 2003On Noise Characterization7 Pathological Channels Some very noisy channels have non-gaussian digital filtering noise distribution  Their pedestal distribution is gaussian;  The non-gaussian nature of the noise distribution seems to be generated by the digital filtering reconstruction  A limited range gaussian fit underestimates the noise, and hence overestimates the occupancy  They obviously need special treatment...  Seems to be limited to some EMEC channels in layers 1 and 2 run 12191 Kanaya Ch1024 pedrms Ch1024 noise

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