TY - JOUR
T1 - Robust estimation of scattering in pulsar timing analysis
AU - Lentati, L.
AU - Kerr, M.
AU - Dai, S.
AU - Shannon, R. M.
AU - Hobbs, G.
AU - Osłowski, S.
PY - 2017
Y1 - 2017
N2 - We present a robust approach to incorporating models for the time-variable broadening of the pulse profile due to scattering in the ionized interstellar medium into profile-domain pulsar timing analysis. We use this approach to simultaneously estimate temporal variations in both the dispersion measure (DM) and scattering, together with a model for the pulse profile that includes smooth evolution as a function of frequency, and the pulsar's timing model. We show that fixing the scattering time-scales when forming time-of-arrival estimates, as has been suggested in the context of traditional pulsar timing analysis, can significantly underestimate the uncertainties in both DM and the arrival time of the pulse, leading to bias in the timing parameters. We apply our method using a new, publicly available, GPU-accelerated code, both to simulations and observations of the millisecond pulsar PSR J1643−1224. This pulsar is known to exhibit significant scattering variability compared to typical millisecond pulsars, and we find including low-frequency (<1 GHz) data without a model for these scattering variations leads to significant periodic structure in the DM, and also biases the astrometric parameters at the 4σ level, for example, changing proper motion in right ascension by 0.50 ñ 0.12. If low-frequency observations are to be included when significant scattering variations are present, we conclude it is necessary to not just model those variations, but also to sample the parameters that describe the variations simultaneously with all other parameters in the model, a task for which profile domain pulsar timing is ideally suited.
AB - We present a robust approach to incorporating models for the time-variable broadening of the pulse profile due to scattering in the ionized interstellar medium into profile-domain pulsar timing analysis. We use this approach to simultaneously estimate temporal variations in both the dispersion measure (DM) and scattering, together with a model for the pulse profile that includes smooth evolution as a function of frequency, and the pulsar's timing model. We show that fixing the scattering time-scales when forming time-of-arrival estimates, as has been suggested in the context of traditional pulsar timing analysis, can significantly underestimate the uncertainties in both DM and the arrival time of the pulse, leading to bias in the timing parameters. We apply our method using a new, publicly available, GPU-accelerated code, both to simulations and observations of the millisecond pulsar PSR J1643−1224. This pulsar is known to exhibit significant scattering variability compared to typical millisecond pulsars, and we find including low-frequency (<1 GHz) data without a model for these scattering variations leads to significant periodic structure in the DM, and also biases the astrometric parameters at the 4σ level, for example, changing proper motion in right ascension by 0.50 ñ 0.12. If low-frequency observations are to be included when significant scattering variations are present, we conclude it is necessary to not just model those variations, but also to sample the parameters that describe the variations simultaneously with all other parameters in the model, a task for which profile domain pulsar timing is ideally suited.
UR - https://hdl.handle.net/1959.7/uws:64134
U2 - 10.1093/mnras/stx580
DO - 10.1093/mnras/stx580
M3 - Article
SN - 0035-8711
VL - 468
SP - 1474
EP - 1485
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 2
ER -