1 / 15

Dead time Vs Data collection for AMS

Dead time Vs Data collection for AMS. P. Zuccon – INFN Perugia. The Problem. As the dead time after a trigger increases the data collection efficiency becomes smaller. What is the fraction of the data collected by AMS02 as function of the dead time?

marnin
Télécharger la présentation

Dead time Vs Data collection for AMS

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Dead time Vs Data collection for AMS P. Zuccon – INFN Perugia P.Zuccon -- INFN Perugia

  2. The Problem • As the dead time after a trigger increases the data collection efficiency becomes smaller. • What is the fraction of the data collected by AMS02 as function of the dead time? • Let’s assume that the time difference between the arrival of two cosmic rays is distributed as an exponential with constant equal to the average delta t (t) or the average rate (n). let’s indicate with T the trigger dead time. The fraction of collected events will be: Average number of events within the time T if the physical rate is t P.Zuccon -- INFN Perugia

  3. Fraction of collected events P.Zuccon -- INFN Perugia

  4. The Problem • To complete the picture we must know • what is the range of rates AMS will be exposed to • how much time AMS will be exposed to each rate • Combine everything to get the collected statistics vs dead time The rate seen by AMS depends on: The AMS acceptance geometry trigger configuration The cosmic rays spectrum geomagnetic latitude Solar activity P.Zuccon -- INFN Perugia

  5. Trigger for Protons from AMS MC Cfr: P.Zuccon AMS Analysis meeting 31 March 2005 P.Zuccon -- INFN Perugia

  6. Time spent at various geomagnetic latitudes • ISS orbit spans uniformly the region lat [-51.7,51.7] lon [-180,180] • The time spent in a given latitude interval is proportional to the selected area • Consider 10 geomagnetic latitude intervals as for AMS-01 and map they to the geographical coo (see plot) • Calculate the area corresponding to the various geomagnetic latitude bands ref: P.Zuccon PhD thesis P.Zuccon -- INFN Perugia

  7. Evaluate the rate Integral rate from Ek Threshold to INF • From AMS-01 data evaluate: • the cut-off value vs the geomagnetic latitude • the fractional contribution of the under cut-off protons • Cosmic protons flux parameterization Vs solar activity: M.Honda et al . (HKKM) ICRC07 • The flux is parameterized w.r.t. the counts of the Climax neutron monitor. • The average Climax count for 1988-1989 (same solar cycle as 2010-2011) is 3768 • Take the trigger acceptance as 1 m2 sr, and calculate the trigger rate for the spectrum in the range [cut-off value, INF] • Correct for the contribution of under cut-off protons • Add further 10% to account for He flux P.Zuccon -- INFN Perugia

  8. Rates Calculation AMS-01 1998 (1 m2sr) AMS-02(1 m2sr) (2010-11) P.Zuccon -- INFN Perugia

  9. Collected Statistic Trigger efficiency as function of the dead time and the geomagnetic latitude Cosmic protons P.Zuccon -- INFN Perugia

  10. Collected Statistic Trigger efficiency as function of the dead time and the geomagnetic latitude Cosmic protons A=1 m 2 sr A=2 m 2 sr P.Zuccon -- INFN Perugia

  11. P.Zuccon -- INFN Perugia

  12. P.Zuccon -- INFN Perugia

  13. P.Zuccon -- INFN Perugia

  14. P.Zuccon -- INFN Perugia

  15. P.Zuccon -- INFN Perugia

More Related