New MuE

1. New MuE Dmitry Chirkin, UW Madison

2. Photon propagation approximations • cascades • near: • far: • combined: • diffusive formula actually also gives correct limit at small distances but is difficult to compute (see icecube/201102007) • muons • near: • far: • combined:

3. cascades ~1/r2 far numerical merged small angle nearby ~1/r exp(-r/lp) ppc simulation

4. cascades fit

5. muons ~1/r far merged nearby ~1/r1/2 exp(-r/lp) ppc simulation

6. muons fit

7. Dependence on <cosq> and fSL cascades muons

8. Layered ice

9. 460 m – 260 m cascade muon cascade muon

10. 220 m – 20 m cascade muon cascade muon

11. -20 m – -220 m cascade muon cascade muon

12. -260 m – -460 m cascade muon cascade muon

13. Relation to energy Cherenkov photons per meter of bare muon track ice density in Marek’s report Ice density at center of IceCube dE/dx=a+bE ice density in Marek’s report meters of bare muon track per GeV of cascade

14. Energy likelihood

15. Systematic uncertainties • The Poisson likelihood describes only the statistical uncertainties • The flux function parametrizations given here are approximations • There are fluctuations in photon production along a muon track

16. Muons

17. Cascades

18. Adding systematics: marginalization Poisson (statistics only): Log-normal (systematics only) Integrated statistics over systematics:

19. Profile likelihood approach

20. poisson log-normal marginalized profile Lf gaus. approx.

21. poisson log-normal marginalized profile Lf gaus. approx.

22. poisson log-normal marginalized profile Lf gaus. approx.

23. poisson log-normal marginalized profile Lf gaus. approx.

24. poisson log-normal marginalized profile Lf gaus. approx.

25. poisson log-normal marginalized profile Lf gaus. approx.

26. Muon energy reconstruction Bulk ice/old MuE distance cut at 200 m distance cut at 25 m Layered ice/new MuE distance cut at 200 m Poisson likelihood Full likelihood: Poisson + log-normal Sytematic Detailed losses reconstruction (NNLS)

27. Bulk ice, Poisson likelihood Loose CAP to COG cut at 200 m

28. Bulk ice, Poisson likelihood Tight CAP to COG cut at 25 m

29. Bulk ice, full likelihood Tight CAP to COG cut at 25 m

30. Bulk ice, full likelihood Loose CAP to COG cut at 190 m

31. Layered ice, Poisson likelihood

32. Layered ice, Full likelihood

33. Example event

34. Detailed loss reconstruction • Hypothesis: • a muon track • cascade losses every 15 m • Form a matrix Aij of probabilities to see light from muon or cascade j with number of emitted photons nj in DOM i. The charges are then described by log likelihood • Siqi log mi - mi - log qi! with mi=SjAijnj. If Aij can be inverted the solution is nj=Aij-1qj. Otherwise a good solution is given by NNLS* algorithm. * non negative least squares log linear closest hit DOMs (every ~125 m) scale

35. Detailed loss reconstruction With a solution nj the average total charge in such an event is calculated with Simi=SiSjAijnj. It is typically within 5% of the total charge in the event. Total energy losses are reconstructed to within 30% (0.12 in log10E), next slide

36. Detailed reconstruction: DE

37. Detailed reconstruction: DE/Dx

38. Starting energy of the muon From the average muon energy loss treatment:

39. Detailed reconstruction: Eini

40. Cascade energy reconstruction

41. Cascades: Poisson likelihood

42. Cascades: Full likelihood

43. Summary • New MuE: • uses improved updated and ppc-calibrated flux functions • uses poisson or poisson+log-normal description of uncertainties • reconstructs cascade energy • performs detailed reconstruction of muon energy losses