Presentation is loading. Please wait.

Presentation is loading. Please wait.

Sept. 12-15, 2005M. Block, Phystat 05, Oxford PHYSTAT 05 - Oxford 12th - 15th September 2005 Statistical problems in Particle Physics, Astrophysics and.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Sept. 12-15, 2005M. Block, Phystat 05, Oxford PHYSTAT 05 - Oxford 12th - 15th September 2005 Statistical problems in Particle Physics, Astrophysics and."— Presentation transcript:

1 Sept. 12-15, 2005M. Block, Phystat 05, Oxford PHYSTAT 05 - Oxford 12th - 15th September 2005 Statistical problems in Particle Physics, Astrophysics and Cosmology “Sifting data in the real world” Martin Block Northwestern University

2 Sept. 12-15, 2005M. Block, Phystat 05, Oxford “Sifting Data in the Real World”, M. Block, arXiv:physics/0506010 (2005). “Fishing” for Data

3 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

4 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Generalization of the Maximum Likelihood Function

5 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Hence,minimize  i  (z), or equivalently, we minimize  2   i  2 i

6 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Problem with Gaussian Fit when there are Outliers

7 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

8 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Robust Feature: w(z)  1/  i 2 for large  i 2

9 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Lorentzian Fit used in “Sieve” Algorithm

10 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Why choose normalization constant  =0.179 in Lorentzian  0 2 ? Computer simulations show that the choice of  =0.179 tunes the Lorentzian so that minimizing  0 2, using data that are gaussianly distributed, gives the same central values and approximately the same errors for parameters obtained by minimizing these data using a conventional  2 fit. If there are no outliers, it gives the same answers as a  2 fit. Hence, using the tuned Lorentzian  0 2, much like using the Hippocratic oath, does “no harm”.

11 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

12 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

13 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

14 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

15 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

16 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

17 Sept. 12-15, 2005M. Block, Phystat 05, Oxford “Sieve’’ Algorithm: SUMMARY

18 Sept. 12-15, 2005M. Block, Phystat 05, Oxford All cross section data for E cms > 6 GeV, pp and pbar p, from Particle Data Group

19 Sept. 12-15, 2005M. Block, Phystat 05, Oxford All  data (Real/Imaginary of forward scattering amplitude), for E cms > 6 GeV, pp and pbar p, from Particle Data Group

20 Sept. 12-15, 2005M. Block, Phystat 05, Oxford We use real analytical amplitudes that saturate the Froissart bound with the term ln 2 ( /m), where is the laboratory energy and m is the proton (pion) mass. We simultaneously fit the cross section  and  (the ratio of the real to the imaginary portion of the forward scattering amplitude), where: Fitting the “Sieved” pp and  p data with analytic amplitudes

21 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Only 3 Free Parameters However, only 2, c 1 and c 2, are needed in cross section fits !

22 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Cross section model fits for E cms > 6 GeV, anchored at 4 GeV, pp and pbar p, after applying “Sieve” algorithm to Real World data

23 Sept. 12-15, 2005M. Block, Phystat 05, Oxford  -value fits for E cms > 6 GeV, anchored at 4 GeV, pp and pbar p, after applying “Sieve” algorithm

24 Sept. 12-15, 2005M. Block, Phystat 05, Oxford What the “Sieve” algorithm accomplished for the pp and pbar p data Before imposing the “Sieve algorithm:  2 /d.f.=5.7 for 209 degrees of freedom; Total  2 =1182.3. After imposing the “Sieve” algorithm: Renormalized  2 /d.f.=1.09 for 184 degrees of freedom, for  2 i > 6 cut; Total  2 =201.4. Probability of fit ~0.2. The 25 rejected points contributed 981 to the total  2, an average  2 i of ~39 per point. Similar results were found when fitting  + p and  - p data from the Particle Data Group (not shown due to lack of time!)

25 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Cross section and  -value predictions for pp and pbar-p The errors are due to the statistical uncertainties in the fitted parameters LHC prediction Cosmic Ray Prediction

26 Sept. 12-15, 2005M. Block, Phystat 05, Oxford 100 data points, gaussianly distributed on the straight line y=1-2x; 20 noise points, randomly distributed, with  2 i >6. After  2 i >6 cut: Best fit is y=0.998- 2.014x; R  2 min / =1.01; fit to all data has  2 min / =4.8

27 Sept. 12-15, 2005M. Block, Phystat 05, Oxford 100 data points, gaussianly distributed about the constant y=10; 40 noise points, randomly distributed, with  2 i >4. After  2 i >4 cut: Best fit is y=9.98  R  2 min / =1.09; fit to all data has  2 min / =4.39.

28 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Lessons learned from computer studies of a straight line and a constant model where  is the parameter error found in the  2 fit

29 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

30 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

31 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

32 Sept. 12-15, 2005M. Block, Phystat 05, Oxford  2 renorm =  2 obs / R -1  renorm = r  2  obs, where  is the parameter error

33 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

34 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

35 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

36 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

37 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

38 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

39 Sept. 12-15, 2005M. Block, Phystat 05, Oxford 100 data points, gaussianly distributed about the parabola y=1+2x +0.5x 2 ; 35 noise points, randomly distributed about nearby parabola y=12+2x+0.2x 2 ; We have 13 “inliers”. After  2 i >6 cut: 113 points are kept; Best fit is y=1.23+2.04x+0.48x 2 BONUS: Seems to also work reasonably well in separating two similar distributions! What happens when we try to separate two similar distributions?

40 Sept. 12-15, 2005M. Block, Phystat 05, Oxford log 2 ( /m p ) fit compared to log( /m p ) fit: All known n-n data

41 Sept. 12-15, 2005M. Block, Phystat 05, Oxford  p log 2 ( /m) fit, compared to the  p even amplitude fit M. Block and F. Halzen, Phys Rev D 70, 091901, (2004)

42 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

43 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

44 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

45 Sept. 12-15, 2005M. Block, Phystat 05, Oxford

46 Sept. 12-15, 2005M. Block, Phystat 05, Oxford  2 renorm =  2 obs / R -1  renorm = r  2  obs, where  is the parameter error

47 Sept. 12-15, 2005M. Block, Phystat 05, Oxford All cross section data for E cms > 6 GeV,  + p and  - p, from Particle Data Group

48 Sept. 12-15, 2005M. Block, Phystat 05, Oxford All  data (Real/Imaginary of forward scattering amplitude), for E cms > 6 GeV,  + p and  - p, from Particle Data Group

49 Sept. 12-15, 2005M. Block, Phystat 05, Oxford Cross section model fits for E cms > 6 GeV, anchored at 2.6 GeV,  + p and  - p, after applying “Sieve” algorithm to Real World data

50 Sept. 12-15, 2005M. Block, Phystat 05, Oxford  -value fits for E cms > 6 GeV, anchored at 2.6 GeV,  + p and  - p, after applying “Sieve” algorithm

Download ppt "Sept. 12-15, 2005M. Block, Phystat 05, Oxford PHYSTAT 05 - Oxford 12th - 15th September 2005 Statistical problems in Particle Physics, Astrophysics and."

Similar presentations

What Could We Do better? Alternative Statistical Methods Jim Crooks and Xingye Qiao.

What Could We Do better? Alternative Statistical Methods Jim Crooks and Xingye Qiao.
Modeling of Data. Basic Bayes theorem Bayes theorem relates the conditional probabilities of two events A, and B: A might be a hypothesis and B might.

Modeling of Data. Basic Bayes theorem Bayes theorem relates the conditional probabilities of two events A, and B: A might be a hypothesis and B might.
Sept. 7-13, 2005M. Block, Prague, c2cr 20051 The Elusive p-air Cross Section.

Sept. 7-13, 2005M. Block, Prague, c2cr The Elusive p-air Cross Section.
8. Statistical tests 8.1 Hypotheses K. Desch – Statistical methods of data analysis SS10 Frequent problem: Decision making based on statistical information.

8. Statistical tests 8.1 Hypotheses K. Desch – Statistical methods of data analysis SS10 Frequent problem: Decision making based on statistical information.
4/28/05 M. BlockAspen Cosmic Ray Workshop1 The Elusive p-air Cross Section Martin Block Northwestern University 1)Sifting data in the real world 2) Obtaining.

4/28/05 M. BlockAspen Cosmic Ray Workshop1 The Elusive p-air Cross Section Martin Block Northwestern University 1)Sifting data in the real world 2) Obtaining.
G. Cowan Lectures on Statistical Data Analysis 1 Statistical Data Analysis: Lecture 10 1Probability, Bayes’ theorem, random variables, pdfs 2Functions.

G. Cowan Lectures on Statistical Data Analysis 1 Statistical Data Analysis: Lecture 10 1Probability, Bayes’ theorem, random variables, pdfs 2Functions.
458 More on Model Building and Selection (Observation and process error; simulation testing and diagnostics) Fish 458, Lecture 15.

458 More on Model Building and Selection (Observation and process error; simulation testing and diagnostics) Fish 458, Lecture 15.
April 15-19, 2007M. Block, Aspen Workshop Cosmic Ray Physics 2007 1 Imposing the Froissart Bound on Hadronic Interactions: Part I, p-air cross sections.

April 15-19, 2007M. Block, Aspen Workshop Cosmic Ray Physics Imposing the Froissart Bound on Hadronic Interactions: Part I, p-air cross sections.
Statistics.

Statistics.
September 17-20, 2003.Kenichi Hatakeyama1 Soft Double Pomeron Exchange in CDF Run I Kenichi Hatakeyama The Rockefeller University for the CDF Collaboration.

September 17-20, 2003.Kenichi Hatakeyama1 Soft Double Pomeron Exchange in CDF Run I Kenichi Hatakeyama The Rockefeller University for the CDF Collaboration.
April 15-19, 2007M. Block, Aspen Workshop Cosmic Ray Physics 2007 1 Imposing the Froissart Bound on Hadronic Interactions: Part II, Deep Inelastic Scattering.

April 15-19, 2007M. Block, Aspen Workshop Cosmic Ray Physics Imposing the Froissart Bound on Hadronic Interactions: Part II, Deep Inelastic Scattering.
Diffractive and Total pp cross sections at LHC K. Goulianos EDS 2009, June 29-July 3 1 Diffractive and Total pp Cross Sections at LHC Konstantin Goulianos.

Diffractive and Total pp cross sections at LHC K. Goulianos EDS 2009, June 29-July 3 1 Diffractive and Total pp Cross Sections at LHC Konstantin Goulianos.
Horng-Chyi HorngStatistics II41 Inference on the Mean of a Population - Variance Known H 0 :  =  0 H 0 :  =  0 H 1 :    0, where  0 is a specified.

Horng-Chyi HorngStatistics II41 Inference on the Mean of a Population - Variance Known H 0 :  =  0 H 0 :  =  0 H 1 :    0, where  0 is a specified.
Physics 114: Lecture 15 Probability Tests & Linear Fitting Dale E. Gary NJIT Physics Department.

Physics 114: Lecture 15 Probability Tests & Linear Fitting Dale E. Gary NJIT Physics Department.
Atmospheric Neutrino Oscillations in Soudan 2

Atmospheric Neutrino Oscillations in Soudan 2
Chapter 15 Modeling of Data. Statistics of Data Mean (or average): Variance: Median: a value x j such that half of the data are bigger than it, and half.

Chapter 15 Modeling of Data. Statistics of Data Mean (or average): Variance: Median: a value x j such that half of the data are bigger than it, and half.
M. Giorgini University of Bologna, Italy, and INFN Limits on Lorentz invariance violation in atmospheric neutrino oscillations using MACRO data From Colliders.

M. Giorgini University of Bologna, Italy, and INFN Limits on Lorentz invariance violation in atmospheric neutrino oscillations using MACRO data From Colliders.
Forward - Backward Multiplicity in High Energy Collisions Speaker: Lai Weichang National University of Singapore.

Forward - Backward Multiplicity in High Energy Collisions Speaker: Lai Weichang National University of Singapore.
G. Cowan 2009 CERN Summer Student Lectures on Statistics1 Introduction to Statistics − Day 4 Lecture 1 Probability Random variables, probability densities,

G. Cowan 2009 CERN Summer Student Lectures on Statistics1 Introduction to Statistics − Day 4 Lecture 1 Probability Random variables, probability densities,
Copyright © 2012 by Nelson Education Limited. Chapter 7 Hypothesis Testing I: The One-Sample Case 7-1.

Copyright © 2012 by Nelson Education Limited. Chapter 7 Hypothesis Testing I: The One-Sample Case 7-1.

Similar presentations

Ads by Google