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LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 1 BlockNormal Near-Online S4 Burst Analysis Keith Thorne Penn State University Relativity Group (Shantanu.

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Presentation on theme: "LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 1 BlockNormal Near-Online S4 Burst Analysis Keith Thorne Penn State University Relativity Group (Shantanu."— Presentation transcript:

1 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 1 BlockNormal Near-Online S4 Burst Analysis Keith Thorne Penn State University Relativity Group (Shantanu Desai, Sam Finn, Tina Lin, John McNabb, Amber Stuver, Tiffany Summerscales) https://gravity.psu.edu/~s4

2 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 2 Why Near-Online Analysis for S4? BlockNormal pipeline (started for S2) now mature, reviewed  Review helped identify some data-conditioning issues LSC Grid computers would have access to RDS frames within a few hours of acquisition (even on Tier2) New utilities (LSCsegFind, LSCdataFind, etc.) improved ability to automate pipelines  Could set up daily processing pipeline Need to prepare now for long-duration science runs (S5, etc.)  Physics results can’t wait for the end of the run  Implement near-online burst analysis for S4

3 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 3 BlockNormal ETG Thresholds: Change-Points (  2 ) »Where variance (   ) or mean (  ) changes »Divides data into blocks of ~constant mean & variance Events (P E ) »Use relative excess power to select exceptional blocks as events »Threshold relative to characteristics (  ,    ) of stationary epochs Cluster adjacent events Use 30ms Coincidence Windows Event threshold Injected signal

4 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 4 Changes for S4 Analysis Data-Conditioning (Thorne, Summerscales) »Automated band-filter tuning, narrow (Kalman) line-finding Vetos (Desai) »Developed Figure-of-Merit to optimize veto selection »Integrated vetos into analysis ETG (Stuver) »Found excess power threshold better than event mean/variance Distributional Analysis(McNabb, Lin) »Test for statistical difference in amplitude distribution of signal and background distributions »Integrated waveform matching (r-statistics) into analysis

5 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 5 Bayesian Rate Statistic Given # of zero-lag (N) background rate (b) Livetime (T) Get probability of true signal rate P(s  N,b,T) Rate limit probability P(< s  N,b,T)

6 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 6 S4 Daily Pipeline Design Starts about 2 AM each day, is done by ~ 9 AM Implemented as condor DAGman pipeline »Used DAGiT templates (John McNabb) to organizes loops Each step is a shell (csh) script »Calls MATLAB executable as needed Could run on any grid with frames from all IFOs »PSU chosen due to MATLAB problem with FedoraCore3

7 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 7 “Original” S4 Run Plan First Week - Tune, set thresholds »Data-Conditioning: Decide on filters, do over-all tuning »Vetoes: Decide on veto channels, set thresholds »ETG: Decide on rates, tune, set thresholds Remaining Weeks - Analyze data on daily basis »Run pipeline automatically each day »Post automated web-page summaries »Staff ‘analysis’ shifts to monitor daily processing At end of run - Finalize, report initial result »Adding DQ cuts on segments could test for systematic errors

8 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 8 Actual S4 Experience External events impacted schedules »Late Installation of LDR Upgrade prevented E12 studies »Instability in segment-finding method Only simplest Data-Conditioning Implemented »Band-pass filters, Low-order whitening filters Threshold Setting based mostly on background rates »Target source is white-noise bursts 20-30ms duration »Initial thresholds set to avoid any chance of event pile-up in IFO Limited bandwidth (6 bands from 96-1024Hz) due to large processing time on bands > 1kHz. Initial Veto Channels chosen from S3 studies Daily Summary pages not implemented until third week (but have been updated for all days)

9 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 9 Initial S4 Results Present thresholds (  2 > 6, P E > 12) give very low background at triple-coincidence (~ 3 events / 50 time lags without r-statistic). https://gravity.psu.edu/~s4/online/DailySummary.html  Need to back this off for distributional analysis (already have per- IFO event samples at range of thresholds) Despite this, high detection rate on hardware injections (i.e.< 1e-21 on 235Hz Sine-Gaussian) https://gravity.psu.edu/~s4/online/HW_Injections_Matches.html  Clearly a great improvement over S2/S3

10 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 10 Per-IFO Event Rates in S4 Smooth falloff with threshold PEPE Predicted Triple-Rate 6 5  10 -6 Hz 8 2  10 -6 Hz 10 2  10 -7 Hz 12 2  10 -8 Hz

11 LIGO- G050142-00-Z 03/23/2005LSC Meeting March 2005 11 Next Steps for S4 Analysis Do Software Injections to get detection yield Form lower-threshold coincidence sample for distributional analysis Check for GRB coincidence with much lower threshold A Somewhat “Radical” Proposal: Only add in changes (data-conditioning, DQ cuts) which actually affect detection yield on simulations, or lower background (non-zero-lag) rates. --> would like to report physics well before S5

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