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S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting First results from the likelihood pipeline S.Klimenko (UF), I.Yakushin (LLO), A.Mercer (UF),G.Mitselmakher.

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Presentation on theme: "S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting First results from the likelihood pipeline S.Klimenko (UF), I.Yakushin (LLO), A.Mercer (UF),G.Mitselmakher."— Presentation transcript:

1 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting First results from the likelihood pipeline S.Klimenko (UF), I.Yakushin (LLO), A.Mercer (UF),G.Mitselmakher (UF) l network WaveBurst pipeline l LIGO-Virgo project 1b results l Coherent energy, x-correlation l S4 results l Summary&Plans

2 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Why one more method for burst detection? l The network WaveBurst pipeline is based on likelihood method (PRD 72, 122002, 2005)  a coherent method for burst detection  allows reconstruction of GW waveforms and source coordinates  works for arbitrary alignment of detectors

3 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Search algorithm l works in time-frequency domain l likelihood formalism independent for each TF sample greatly simplifies calculation of network response l likelihood time-frequency maps l time shifts  use 2D TF time delay filter pick any pixel with fixed (f,t) and calculate pixel amplitudes a2(t,f,  ) and a3(t,f,  ) time-shifting planes 2 & 3 by delay  The amplitudes a1, a2(t,f,  ) and a3(t,f,  ) are used to calculate pixel likelihood L(t,f,  ) f t f t

4 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting L1: 1.1e-22 V1: 1.3e-22 H1: 1.5e-22 likelihood Time-frequency maps sg250Hz,  =0.02sec,  =20,  =150 apply threshold on likelihood and reconstruct clusters

5 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Coherent WaveBurst l Similar approach as for incoherent WaveBurst l Uses most of existing WaveBurst functionality data conditioning: wavelet transform, (rank statistics), pixel selection channel 1 data conditioning: wavelet transform, (rank statistics), pixel selection channel 2 Likelihood TF map event generation data conditioning: wavelet transform, (rank statistics), pixel selection channel 3,…

6 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Likelihood sky maps l xxx sg250Hz,  =0.02sec,  =20,  =150, L1/H1/V1

7 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting LIGO-Virgo simulated noise l Likelihood of triggers on the output of nWB  different types of injections (SG,GAUSS,SN)  background -- 101 time shifts (T=8726400sec) 2L is the total detected energy

8 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Periodic table of burst algorithms A1B2G1 or2 / 3pl A2B4G1 or2 / 3pl gauss1 or2 /3pl gauss4 or2 / 3pl sg235 or2 / 3pl sg820 or2 / 3pl PF33 / 939 / 1060 / 1719 / 719 / 334 / 13 KW26 / 636 / 952 / 1314 / 438 / 611 / 2 PC56 / 1467 / 1976 / 3055 / 23-- EGC52 / 1643 / 1266 / 2332 / 1360 / 1932 / 13 MF28 / 843 / 1355 / 1717 / 820 / 31 / 0 ALF33 / 947 / 1460 / 2028 / 1225 / 36 / 2 QT45 / 2059 / 2376 / 3546 / 1877 / 3962 / 32 WBN4163--628273 false alarm rate 1-3  Hz 3pl – triple coincidence or2 – OR of detector pairs Fraction (%) of detected events

9 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting maximum likelihood statistic Likelihood for Gaussian noise with variance  2 k and GW waveform u: x k [i] – detector output, F k – antenna patterns l Events reconstructed by the pipeline are coincident in time by construction  what is definition of a coincidence? detector response - total energy noise (null) energy detected (signal) energy

10 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting real world analysis l In ideal world where detector noise is always Gaussian: likelihood statistic is sufficient. l In the real world where data is always contaminated with glitches: - the signal consistency statistics are required l Real world analysis strategy use L as detection statistic use power null stream coherent energy as signal consistency statistics

11 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Likelihood distribution Ligo-Virgo noise S4 data

12 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Detection performance as ETG sgQ9701001532353615538491053 WB4.601.321.131.292.042.493.715.00 nWB2.701.230.941.121.652.153.184.01 tuned to FA rate 20  Hz by setting threshold on power in each detector

13 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Coherent energy l Likelihood is a quadratic form: l x i – whitened data streams l C ij depend on antenna patterns and detector sensitivity. For constraint likelihood: g – network sensitivity incoherent coherent

14 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting X-correlation for misaligned detectors l S-statistic l Cauchy-statistic  network global x-correlation coefficient l Similar to r-statistic the KS test can be applied arbitrary detectorsaligned detectors

15 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Network x-correlation l powerful signal consistency test different from the NULL stream SG injections S4 background triggers

16 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting End-to-End pipeline sgQ9701001532353615538491053 WB+R4.71.41.21.32.12.63.95.4 WBN3.51.51.21.52.22.94.66.1 l In addition to excess power cuts apply selection cuts based on the likelihood x-correlation terms  works for arbitrary detector alignment l False alarm (100 time lags) 0.2 mkHz l Results are very preliminary  no DQ flags were applied  post-processing election cuts are not tuned

17 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Pipeline performance l Search over the entire sky with good angular resolution can be computationally very intensive l nWB pipeline performance for all sky search with 1 o resolution (65000 sky locations) and 101 time lags  cit 2.2GHz 64 bit obteron – 1. 0 sec/sec  Llo 3.4GHz 32 bit Xeon - 1.6 sec/sec l nWB performance is comparable to the incoherent WaveBurst pipeline  typical run time on LLO cluster for S4 data is 1 day

18 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Summary l network WaveBurst pipeline (nWB) based on likelihood analysis is operational.  LIGO-Virgo project 1b data: nWB looks good in “ideal world”  S4 data: results consistent with the standard WB+R pipeline  Excellent computational performance l x-correlation coefficients can be defined for arbitrary networks which offers a waveform consistency test complementary to Null stream

19 S.Klimenko, G060091-00-Z, March 20, 2006, LSC meeting Plans l Finalize tuning of selection cuts & S4 data analysis l study coordinate and waveform reconstruction l try algorithm on LIGO-GEO and LIGO-Virgo data l run online coherent search on S5 data l Produce likelihood statistic for triggered population search (with S.Mohanty) l perform BH-BH merger search

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