TY - JOUR
T1 - Improving gravitational-wave parameter estimation using Gaussian process regression
AU - Moore, Christopher J.
AU - Berry, Christopher Philip Luke
AU - Chua, Alvin J.K.
AU - Gair, Jonathan R.
N1 - Publisher Copyright:
© 2016 American Physical Society.
PY - 2016/3/1
Y1 - 2016/3/1
N2 - Folding uncertainty in theoretical models into Bayesian parameter estimation is necessary in order to make reliable inferences. A general means of achieving this is by marginalizing over model uncertainty using a prior distribution constructed using Gaussian process regression (GPR). As an example, we apply this technique to the measurement of chirp mass using (simulated) gravitational-wave signals from binary black holes that could be observed using advanced-era gravitational-wave detectors. Unless properly accounted for, uncertainty in the gravitational-wave templates could be the dominant source of error in studies of these systems. We explain our approach in detail and provide proofs of various features of the method, including the limiting behavior for high signal-to-noise, where systematic model uncertainties dominate over noise errors. We find that the marginalized likelihood constructed via GPR offers a significant improvement in parameter estimation over the standard, uncorrected likelihood both in our simple one-dimensional study, and theoretically in general. We also examine the dependence of the method on the size of training set used in the GPR; on the form of covariance function adopted for the GPR, and on changes to the detector noise power spectral density.
AB - Folding uncertainty in theoretical models into Bayesian parameter estimation is necessary in order to make reliable inferences. A general means of achieving this is by marginalizing over model uncertainty using a prior distribution constructed using Gaussian process regression (GPR). As an example, we apply this technique to the measurement of chirp mass using (simulated) gravitational-wave signals from binary black holes that could be observed using advanced-era gravitational-wave detectors. Unless properly accounted for, uncertainty in the gravitational-wave templates could be the dominant source of error in studies of these systems. We explain our approach in detail and provide proofs of various features of the method, including the limiting behavior for high signal-to-noise, where systematic model uncertainties dominate over noise errors. We find that the marginalized likelihood constructed via GPR offers a significant improvement in parameter estimation over the standard, uncorrected likelihood both in our simple one-dimensional study, and theoretically in general. We also examine the dependence of the method on the size of training set used in the GPR; on the form of covariance function adopted for the GPR, and on changes to the detector noise power spectral density.
UR - http://www.scopus.com/inward/record.url?scp=84961226291&partnerID=8YFLogxK
UR - http://www.scopus.com/inward/citedby.url?scp=84961226291&partnerID=8YFLogxK
U2 - 10.1103/PhysRevD.93.064001
DO - 10.1103/PhysRevD.93.064001
M3 - Article
AN - SCOPUS:84961226291
SN - 2470-0010
VL - 93
JO - Physical Review D
JF - Physical Review D
IS - 6
M1 - 064001
ER -