First results and future prospects for dual-harmonic searches for gravitational waves from spinning neutron stars
First results and future prospects for dual-harmonic searches for gravitational waves from spinning neutron stars
We investigate a method to incorporate signal models that allow an additional frequency harmonic in searches for gravitational waves from spinning neutron stars. We assume that emission is given by the general triaxial non-aligned model of Jones, whose waveform under certain conditions reduces to that of a biaxial precessing star, or a simple rigidly rotating triaxial aligned star. The triaxial non-aligned and biaxial models can produce emission at both the star's rotation frequency (f) and 2f, whilst the latter only emits at 2f. We have studied parameter estimation for signal models using both a set of physical source parameters and a set of waveform parameters that remove a degeneracy. We have assessed the signal detection efficiency, and used Bayesian model selection to investigate how well we can distinguish between the three models. We found that for signal-to-noise ratios (SNRs) ?6, there is no significant loss in efficiency if performing a search for a signal at f and 2f when the source is only producing emission at 2f. However, for sources with emission at both f and 2f, signals could be missed by a search only at 2f. We also find that for a triaxial aligned source, the correct model is always favoured, but for a triaxial non-aligned source it can be hard to distinguish between the triaxial non-aligned model and the biaxial model, even at high SNR. Finally, we apply the method to a selection of known pulsars using data from the LIGO fifth science run. We give the first upper limits on gravitational wave amplitude at both f and 2f and apply the model selection criteria on real data.
gravitational waves, methods: data analysis, methods: statistical, stars: neutron, pulsars: general
4399-4420
Pitkin, M.
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Gill, C.
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Jones, D. I.
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Woan, G.
6315a80a-3dd2-411b-9c3a-c038d7751cf4
Davies, G.S.
7ca7701f-a0b6-4400-ab7f-da03d431d882
11 November 2015
Pitkin, M.
a087910b-5937-42c5-b727-12ec93d81480
Gill, C.
11bbe58e-e88f-4530-9311-bea8996986ad
Jones, D. I.
b8f3e32c-d537-445a-a1e4-7436f472e160
Woan, G.
6315a80a-3dd2-411b-9c3a-c038d7751cf4
Davies, G.S.
7ca7701f-a0b6-4400-ab7f-da03d431d882
Pitkin, M., Gill, C., Jones, D. I., Woan, G. and Davies, G.S.
(2015)
First results and future prospects for dual-harmonic searches for gravitational waves from spinning neutron stars.
Monthly Notices of the Royal Astronomical Society, 453 (4), .
(doi:10.1093/mnras/stv1931).
Abstract
We investigate a method to incorporate signal models that allow an additional frequency harmonic in searches for gravitational waves from spinning neutron stars. We assume that emission is given by the general triaxial non-aligned model of Jones, whose waveform under certain conditions reduces to that of a biaxial precessing star, or a simple rigidly rotating triaxial aligned star. The triaxial non-aligned and biaxial models can produce emission at both the star's rotation frequency (f) and 2f, whilst the latter only emits at 2f. We have studied parameter estimation for signal models using both a set of physical source parameters and a set of waveform parameters that remove a degeneracy. We have assessed the signal detection efficiency, and used Bayesian model selection to investigate how well we can distinguish between the three models. We found that for signal-to-noise ratios (SNRs) ?6, there is no significant loss in efficiency if performing a search for a signal at f and 2f when the source is only producing emission at 2f. However, for sources with emission at both f and 2f, signals could be missed by a search only at 2f. We also find that for a triaxial aligned source, the correct model is always favoured, but for a triaxial non-aligned source it can be hard to distinguish between the triaxial non-aligned model and the biaxial model, even at high SNR. Finally, we apply the method to a selection of known pulsars using data from the LIGO fifth science run. We give the first upper limits on gravitational wave amplitude at both f and 2f and apply the model selection criteria on real data.
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Accepted/In Press date: 18 August 2015
e-pub ahead of print date: 17 September 2015
Published date: 11 November 2015
Keywords:
gravitational waves, methods: data analysis, methods: statistical, stars: neutron, pulsars: general
Organisations:
Applied Mathematics
Identifiers
Local EPrints ID: 404311
URI: http://eprints.soton.ac.uk/id/eprint/404311
ISSN: 1365-2966
PURE UUID: 9ca0ce11-b69e-44cb-bf8a-86a8067c343e
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Date deposited: 04 Jan 2017 15:09
Last modified: 16 Mar 2024 03:06
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Author:
M. Pitkin
Author:
C. Gill
Author:
G. Woan
Author:
G.S. Davies
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