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Methods for flow analysis in ALICE FLOW package

Methods for flow analysis in ALICE FLOW package. Ante Bilandzic Trento, 15.09.2009. Outline. Anisotropic flow From theorists’ point of view From experimentalists’ point of view Multiparticle azimuthal correlations Methods for flow analysis implemented in ALICE flow package

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Methods for flow analysis in ALICE FLOW package

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  1. Methods for flow analysis in ALICE FLOW package Ante BilandzicTrento,15.09.2009

  2. Outline • Anisotropic flow • From theorists’ point of view • From experimentalists’ point of view • Multiparticle azimuthal correlations • Methods for flow analysis implemented in ALICE flow package • 2-particle methods • Multiparticle methods (4-, 6- and 8- particle methods) • Genuine multiparticle methods • Recent development for ALICE: Q-cumulants • Method comparison • Idealistic simulations ‘on the fly’ • Realistic pp simulations (Pythia) • Realistic heavy-ion simulations (Therminator)

  3. Anisotropic flow (th) Azimuthal distributions of particles measured with respect to reaction plane (spanned by impact parameter vector and beam axis) are not isotropic. • S. Voloshin and Y. Zhang (1996): • Harmonics vn quantify anisotropic flow

  4. Anisotropic flow (exp) • Since reaction plane cannot be measured e-b-e, consider the quantities which do not depend on it’s orientation: multiparticle azimuthal correlations • Basic underlying assumption of flow analysis: If only flow correlations are present we can write • Cool idea but already at this level there are two important issues • Statistical flow fluctuations e-b-e, what we measure is actually: • Other sources of correlations (systematic bias a.k.a. nonflow):

  5. Methods to measure flow • Measure the flow with rapidity gaps (using the PMD and FMDs) • advantage: most of nonflow is due to short range correlations, thus using rapidity gaps suppresses nonflow • disadvantage: not known how much nonflow is supressed, results are model dependent and "long range" rapidity correlations are not modeled very well • Measure the deflection of the spectators at beam and target rapidity (v1 in the ZDC) • advantages: 1) nonflow is really very much suppressed, 2) fluctuations are also decoupled from midrapidity source • disadvantage: small resolution c, not an easy measurement • Measure flow using multiparticle correlations All three methods for measuring flow are used in ALICE, but in remainder of the talk will focus only on the last one

  6. Multiparticle azimuthal correlations • Typically nonflow correlations involve only few particles. Based purely on combinatorial grounds: • One can use 2- and 4-particle correlations to estimate flow only if: • It is possible to obtain flow estimate from the genuine multiparticle correlation (Ollitrault et al). In this case one reaches the theoretical limit of applicability: • Can we now relax once we have devised multiparticle correlations to estimate flow experimentally?

  7. There are some more issues… • Basic problem: How to calculate multiparticle correlations? Naïve approach leads to evaluation of nested loops over heavy-ion data, certainly not feasible • Numerical stability of flow estimates? • Measured azimuthal correlations are strongly affected by any inefficiencies in the detector acceptance • Is one pass over data enough or not to correct for it? • Can we also estimate subdominant flow harmonics? • Besides the fact that flow fluctuates e-b-e, and very likely also the systematic bias coming from nonflow, the multiplicity fluctuates as well e-b-e

  8. In the rest of the talk • Outline of the methods based on multiparticle azimuthal correlations which were developed by various authors to tackle all these issues and which were implemented in the ALICE FLOW package • Emphasis will be given to cumulants (in particular to Q-cumulants – a method recently developed for ALICE which is essentially just another way to calculate cumulants with potential improvements) • Notation: In what follows I will use frequently phrase “non-weighted Q-vectorevaluated in harmonic n” for the following:

  9. Methods implemented for ALICE(naming conventions) • MCEP = Monte Carlo Event Plane • SP = Scalar Product • GFC = Generating Function Cumulants • QC = Q-cumulants • FQD = Fitting q-distribution • LYZ = Lee-Yang Zero (sum and product) • LYZEP = Lee-Yang Zero Event Plane Raimond Snellings, Naomi van der Kolk, ab

  10. MCEP • Using the knowledge of sampled reaction plane event-by-event and calculating directly • Both integrated and differential flow calculated in this way • Flow estimates of all other methods in simulations are being compared to this one

  11. Cumulants: A principle • Ollitrault et al: Imagine that there are only flow and 2-particle nonflow correlations present. Than contributions to measured 2- and 4-particle correlations read • By definition, for detectors with uniform acceptance 2nd and 4th order cumulant are given by

  12. Cumulants: GFC • To circumvent evaluation of nested loops to get multiparticle correlations: Borghini, Dinh and Ollitrault proposed the usage of generating function – used regularly at STAR (and recently at PHENIX):

  13. Cumulants: GFC • Example of numerical instability: making equivalent simulations with fixed multiplicity M = 500 and statistics of N = 105 events, but with different input values for flow input v2 = 0.05 input: v2 = 0.15 GFC method has 2 main limitations: a) not numerically stable for all values of multiplicity, flow and number of events, b) biased by flow fluctuations

  14. Cumulants: QC • Another approach to circumvent evaluation of nested loops to get multiparticle correlations: Sergei Voloshin’s idea to express multiparticle correlations in terms of expressions involving Q-vectors evaluated (in general) in different harmonics • Once you have expressed multiparticle correlations in this way, it is trivial to build up cumulants from them • Publication S. Voloshin, R. Snellings, ab “Flow analysis with Q-cumulants” is in preparation

  15. Demystifying QC • Define average 2- and 4-particle azimuthal correlations for a single event as • Define average 2- and 4-particle azimuthal correlations for all events as and follow the recipe…

  16. QC recipe, part 1 • Evaluate Q-vector in harmonics n and 2nfor a particular event and insert those quantities in the following Eqs: • These Eqs. give exactly the same answer for 2- and 4-particle correlations for a particular event as the one obtained with two and four nested loops, but in almost no CPU time

  17. QC recipe, part 2 • How to obtain exact averages for all events? • By using multiplicity weights! For 2-particle correlation multiplicity weight is M(M-1) and for 4-particle correlation multiplicity weight is M(M-1)(M-2)(M-3) • Now it is trivial to build up 2nd and 4th order cumulant

  18. Method comparisons(series of plots)

  19. Nonflow • Example: input v2 = 0.05, M = 500, N = 5 × 106 and simulate nonflow by taking each particle twice As expected only 2-particle estimates are biased

  20. Flow fluctuations • If the flow fluctuations are Gaussian, the theorists say • Example 1: v2 = 0.05 +/- 0.02 (Gaussian), M= 500, N = 106 Gaussian flow fluctuations affect the methods as predicted

  21. Flow fluctuations • Example 2: v2 in [0.04,0.06] (uniform), M = 500, N = 9 × 106 Uniform flow fluctuations affect the methods differently as the Gaussian fluctuations

  22. Multiplicity fluctuations (small <M>) • Example 1: M = 50 +/- 10 (Gaussian), input fixed v2= 0.075, N = 10 × 106 • LYZ (sum) big statistical spread, SP systematically biased • FQD doing fine, spread for QC is smaller than for GFC

  23. Extracting subdominant harmonic • Example: input v1 = 0.10, v2 = 0.05, M = 500, N = 10 × 106 and estimating subdominant harmonic v2 All methods are fine

  24. Extracting subdominant harmonic • Example: input v2 = 0.05, v4 = 0.10, M = 500, N = 10 × 106 and estimating subdominant harmonic v2 FQD and LYZ (sum) are biased and we still have to tune the LYZ product

  25. Non-uniform acceptance • To correct for the bias on flow estimates coming from the non-uniform acceptance of the detector, several techniques were proposed by various authors: flattening, recentering, etc. • require additional run over data • some of them not applicable for detectors with gaps in azimuthal acceptance (e.g. flattening) • Ollitrault et al proposed evaluating generating functions along fixed directions in the laboratory frame and averaging the results obtained for those directions: • works fine for GFC and LYZ • no need for an additional run over data • Recent: For Q-cumulants it is possible explicitly to calculate and subtract the bias coming from the non-uniform acceptance • applicable to all types of non-uniform acceptance • one run over data enough

  26. Non-uniform acceptance • The terms in yellow counter balance the bias due to non-uniform acceptance, so that QC{2} and QC{4} remain unbiased

  27. Non-uniform acceptance • Example: input v2 = 0.05, M = 500, N = 8 × 106, particles emitted in 60o<f< 90o and 180o <f< 225o ignored • Detector’s azimuthal acceptance has two gaps:

  28. Non-uniform acceptance Zoomed plot from LHS: • SP and FQD in its present form cannot be used if detector has gaps in acceptance • QC{6} and QC{8}: correction still not calculated and implemented, but the idea how to proceed is clear • GFC and LYZ rely on averaging out the bias by making projections on 5 fixed directions – pragmatic approach • QC{2} and QC{4}: the bias is explicitly calculated and subtracted

  29. Numerical stability • Are estimates still numerically stable for very large flow? • Example: input v2 = 0.50, M = 500, N = 106 Zoomed plot from LHS: • LHS: GFC estimates unstable (there is no unique set of points in a complex plain which give stable results for all values of number of events, average multiplicity and flow) • RHS: Methods not based on generating functions (SP and QC) are numerically much more stable

  30. QC factbook • Possible to get both integrated and differential flow in a single run • Not biased by interference between different harmonics: can be applied to extract subdominant harmonics • Not biased by interference between different order estimates for the same harmonic (e.g. you do not need the knowledge of the 8th order estimate to calculate the 2nd order estimate) • Not biased by multiplicity fluctuations: compared to GFC improved results for peripheral collisions • Not biased by numerical errors: compared to GFC no need to tune interpolating parameters (e.g. r0 for GFC, QC has no parameters) • Detector effects can be quantified and corrected for in a single run over data even for the detectors with gaps in azimuthal acceptance • Biased by flow fluctuations

  31. Pythia pp • Realistic pp data simulated with no flow • <M>~ 10, N = 3 × 104 • All multiparticle methods fail (because vn is not >> 1/M) • ZDC will also fail for pp • rapidity gaps do work albeit model dependent

  32. Therminator • Realistic heavy-ion dataset (<M> = 2164, N = 1728): • Clear advantage of multiparticle methods over 2-particle methods (GFC higher orders need tuning of interpolating parameters to suppress numerical instability)

  33. Therminator • More detailed impression: differential flow in pt

  34. Therminator • More detailed impression: differential flow in h

  35. Therminator • Same dataset as before just reducing multiplicity with rapidity cuts to get to the more realistic values (<M> = 634, N = 1722):

  36. Heavy-ions in ALICE • Assuming 100 minbias events/s during a run giving 60k events in the first 10 minutes • But a really safe estimate would be 10 ev/s on average during the whole PbPb run (2 weeks) This shows that with a few minutes of good data taking we can provide the first reliable measurement of flow in ALICE

  37. Thanks!

  38. Backup slides

  39. FQD • Evaluating event-by-event modulus of reduced flow vector and filling the histogram. The resulting distribution is fitted with the theoretical distribution in which flow appears as one of the parameters • Method has 5 serious limitations: a) cannot be used to obtain differential flow, b) theoretical distribution valid only for large multiplicities, c) cannot be used to extract the subdominant harmonic, d) cannot be used for detectors with gaps in azimuthal acceptance, e) biased by flow fluctuations

  40. FQD • Example: input v2 = 0.05, M = 250, each particle taken twice to simulate 2-particle nonflow:

  41. SP • 2-particle method • Using a magnitude of the flow vector as a weight: • un,i is the unit vector of the ith particle (which is excluded from the flow vector Qn) • a and bdenote flow vectors of two independent subevents • Method has 4 serious limitations: a) strongly biased by 2-particle nonflow correlations, b) in its present form biased by inefficiencies in detector acceptance, c) biased by multiplicity fluctuations, d) biased by flow fluctuations

  42. LYZ and LYZEP • Introduced by Ollitrault et al • Gives genuine multiparticle estimate, both for integrated and differential flow • Two version implemented – sum and product • LYZEP additionally provides the event plane and it is based on LYZ (sum) • The method has 3 main limitations: a) one pass over data is not enough, b) not numerically stable for all flow values, c) biased by flow fluctuations

  43. LYZ product • One should first compute for each event the complex-valued function: • Next one should average over events for each value of r and q : • For every q value one must then look for the position of the first positive minimum of the modulus • This is the Lee-Yang zero and an estimate of the integrated flow is given now by

  44. LYZ sum • Start by making the projection to an arbitrary laboratory angle q of the second-harmonic flow vector • The sum generating function is given by • The rest is analogous as in LYZ prod

  45. Demystifying QC • How to use QC to calculate the differential flow? • Denote angles of the particles belonging to the particular bin of interest with y and angles of particles used to determine the reaction plane with f • Define average reduced 2’- and 4’-particle azimuthal correlations for a particular bin in a single event as • Define average reduced 2’- and 4’-particle azimuthal correlations for a particular bin over all events as

  46. QC recipe, part 3 • Evaluate also Q-vector in harmonics n and 2n for particles belonging to the bin of interest in a single event and denote it is as qn and q2n. Plug Qn ,Q2n ,qn andq2ninto • M is the multiplicity of event and m is the multiplicity of particles in a particular bin in that event

  47. QC recipe, part 4 • To get the final average for reduced 2’- and 4’-particle correlations over all events use the slightly modified multiplicity weights: • These Eqs. give exactly the same answer for reduced 2’- and 4’-particle correlations over all events as the one obtained with two and four nested loops, but in almost no CPU time

  48. QC recipe, the final touch and estimate differential flow from them: • Build up the cumulants for differential flow in the spirit of Ollitrault et al:

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