Population Study of Gamma Ray Bursts
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Dec 16, 2005 GWDAW-10, Brownsville Population Study of Gamma Ray Bursts S. D. Mohanty The University of Texas at Brownsville
description
Population Study of Gamma Ray Bursts. S. D. Mohanty The University of Texas at Brownsville. GRB030329 Death of a massive star. GRB050709 (and three others) Evidence for binary NS mergers. Chandra. HETE error circle. (Fox et al , Nature, 2005). - PowerPoint PPT Presentation
Transcript of Population Study of Gamma Ray Bursts
Dec 16, 2005 GWDAW-10, Brownsville
Population Study of Gamma Ray Bursts
S. D. Mohanty
The University of Texas at Brownsville
Dec 16, 2005 GWDAW-10, Brownsville
GRB030329Death of a massive star
Dec 16, 2005 GWDAW-10, Brownsville
GRB050709 (and three others)Evidence for binary NS mergers
Bottom-line: The GW sources we are seeking are visible ~ once a day!
HETE error circle
Chandra
(Fox et al, Nature, 2005)
Dec 16, 2005 GWDAW-10, Brownsville
SWIFT in operation during S5• We should get about 100 GRB triggers
• Large set of triggers and LIGO at best sensitivity = unique opportunity to conduct a deep search in the noise
• Direct coincidence: detection unlikely, only UL
•UL can be improved by combining GW detector data from multiple GRB triggers
• Properties of the GRB population instead of any one individual member
Dec 16, 2005 GWDAW-10, Brownsville
Maximum Likelihood approach
• Data: fixed length segments from multiple IFOs for each GRB– xi for the ith GRB
• Signal: Unknown signals si for the ith GRB.
– Assume a maximum duration for the signals
– Unknown offset from the GRB
• Noise: Assume stationarity
• Maximize the Likelihood over the set of offsets {i} and waveforms {si} over all the observed triggers
– Mohanty, Proc. GWDAW-9, 2005
Dec 16, 2005 GWDAW-10, Brownsville
Detection Statistic
Segment length
Max. over offsets
x1[k]
x2[k]
Cross-correlation (cc) x1[k] x2[k]
offsetIntegration length
i (“max-cc”)
Final detection statistic= i , i=1,..,Ngrb
Form of detection algorithm obtained depends on the prior knowledge used
Dec 16, 2005 GWDAW-10, Brownsville
Analysis pipeline for S2/S3/S4
H1
H2
• Band pass filtering• Phase calibration• Whitening
Correlation coefficient with fixed integration length of 100ms
Maximum over offsets from GRB arrival time
1 for on-source segment
Several (Nsegs) from off-source data
On-source pool of max-cc values
Off-source pool
Data Quality Cut
Wilcoxon rank-sum test Empirical
significance against Nsegs/Ngrbs off-source values
LR statistic: sum of max-cc values
Dec 16, 2005 GWDAW-10, Brownsville
Data Quality: test of homogeneity• Off-source cc values computed with time shifts
• Split the off-source max-cc values into groups according to the time shifts
– Terrestrial cross-correlation may change the distribution of cc values for different time shifts.
• Distributions corresponding to shifts ti and tj
• Two-sample Kolmogorov-Smirnov distance between the distributions
• Collect the sample of KS distances for all pairs of time shifts and test against known null hypothesis distribution
• Results under embargo pending LSC review
Dec 16, 2005 GWDAW-10, Brownsville
Constraining population models
• The distribution of max cc depends on 9 scalar parameters
jk = h, hjk ,
, = +, – j,k = detector 1, 2
x, yjk = df x(f) y*(f) / Sj(f) Sk(f)
• Let the conditional distribution of max-cc be p(i| [
jk ]i) for the ith GRB
Dec 16, 2005 GWDAW-10, Brownsville
Constraining population models
• Conditional distribution of the final statistic is
P(| {[jk ]1, [
jk ]2,…, [jk ]N})
• Astrophysical model: specifies the joint probability distribution of
jk
• Draw N times from jk , then draw once from P(|
{[jk ]1, [
jk ]2,…, [jk ]N})
• Repeat and build an estimate of the marginal density p()
• Acceptance/rejection of astrophysical models
Dec 16, 2005 GWDAW-10, Brownsville
Example
• Euclidean universe
• GRBs as standard candles in GW
• Identical, stationary detectors
• Only one parameter governs the distribution of max-cc : the observed matched filtering SNR
• Astrophysical model: p() = 3 min3 / 4
Dec 16, 2005 GWDAW-10, Brownsville
Example• 100 GRBs; Delay between a GRB and GW = 1.0 sec; Maximum
duration of GW signal = 100 msec
• PRELIMINARY: 90% confidence belt: We should be able to exclude populations with min 1.0; Chances of ~ 5 coincident detection: 1 in 1000 GRBs.
Dec 16, 2005 GWDAW-10, Brownsville
Future
• Modify Likelihood analysis to account for extra information (Bayesian approach)– Prior information about redshift, GRB class (implies
waveforms)
• Use recent results from network analysis– significantly better performance than standard
likelihood
• Diversify the analysis to other astronomical transients
• Use more than one statistic
Dec 16, 2005 GWDAW-10, Brownsville
Probability densities
• The astrophysical distribution is specified by nine scalar quantities
jk = h, hjk , , = +, – j,k = detector 1, 2
• Max-cc density depends on three scalar variables derived from
jk
– Linear combinations with direction dependent weights
– Detector sensitivity variations taken into account at this stage
• Density of final statistic (sum over max-cc) is approximately Gaussian from the central limit theorem
• Confidence belt construction is computationally expensive. Faster algorithm is being implemented.
