14 research outputs found
A GPU-based survey for millisecond radio transients using ARTEMIS
Astrophysical radio transients are excellent probes of extreme physical
processes originating from compact sources within our Galaxy and beyond. Radio
frequency signals emitted from these objects provide a means to study the
intervening medium through which they travel. Next generation radio telescopes
are designed to explore the vast unexplored parameter space of high time
resolution astronomy, but require High Performance Computing (HPC) solutions to
process the enormous volumes of data that are produced by these telescopes. We
have developed a combined software /hardware solution (code named ARTEMIS) for
real-time searches for millisecond radio transients, which uses GPU technology
to remove interstellar dispersion and detect millisecond radio bursts from
astronomical sources in real-time. Here we present an introduction to ARTEMIS.
We give a brief overview of the software pipeline, then focus specifically on
the intricacies of performing incoherent de-dispersion. We present results from
two brute-force algorithms. The first is a GPU based algorithm, designed to
exploit the L1 cache of the NVIDIA Fermi GPU. Our second algorithm is CPU based
and exploits the new AVX units in Intel Sandy Bridge CPUs.Comment: 4 pages, 7 figures. To appear in the proceedings of ADASS XXI, ed.
P.Ballester and D.Egret, ASP Conf. Se
Scattering analysis of LOFAR pulsar observations
We measure the effects of interstellar scattering on average pulse profiles
from 13 radio pulsars with simple pulse shapes. We use data from the LOFAR High
Band Antennas, at frequencies between 110 and 190~MHz. We apply a forward
fitting technique, and simultaneously determine the intrinsic pulse shape,
assuming single Gaussian component profiles. We find that the constant ,
associated with scattering by a single thin screen, has a power-law dependence
on frequency , with indices ranging from to , despite simplest theoretical models predicting
or . Modelling the screen as an isotropic or extremely anisotropic
scatterer, we find anisotropic scattering fits lead to larger power-law
indices, often in better agreement with theoretically expected values. We
compare the scattering models based on the inferred, frequency dependent
parameters of the intrinsic pulse, and the resulting correction to the
dispersion measure (DM). We highlight the cases in which fits of extreme
anisotropic scattering are appealing, while stressing that the data do not
strictly favour either model for any of the 13 pulsars. The pulsars show
anomalous scattering properties that are consistent with finite scattering
screens and/or anisotropy, but these data alone do not provide the means for an
unambiguous characterization of the screens. We revisit the empirical
versus DM relation and consider how our results support a frequency dependence
of . Very long baseline interferometry, and observations of the
scattering and scintillation properties of these sources at higher frequencies,
will provide further evidence.Comment: 24 pages, 23 figures, supplementary appendi
Pulsar polarisation below 200 MHz: Average profiles and propagation effects
Aims: We present the highest-quality polarisation profiles to date of 16 non-recycled pulsars and four millisecond pulsars, observed below 200 MHz with the LOFAR high-band antennas. Based on the observed profiles, we perform an initial investigation of expected observational effects resulting from the propagation of polarised emission in the pulsar magnetosphere and the interstellar medium.
Methods: The polarisation data presented in this paper have been calibrated for the geometric-projection and beam-shape effects that distort the polarised information as detected with the LOFAR antennas. We have used RM Synthesis to determine the amount of Faraday rotation in the data at the time of the observations. The ionospheric contribution to the measured Faraday rotation was estimated using a model of the ionosphere. To study the propagation effects, we have compared our low-frequency polarisation observations with archival data at 240, 400, 600, and 1400 MHz.
Results: The predictions of magnetospheric birefringence in pulsars have been tested using spectra of the pulse width and fractional polarisation from multifrequency data. The derived spectra offer only partial support for the expected effects of birefringence on the polarisation properties, with only about half of our sample being consistent with the model's predictions. It is noted that for some pulsars these measurements are contaminated by the effects of interstellar scattering. For a number of pulsars in our sample, we have observed significant variations in the amount of Faraday rotation as a function of pulse phase, which is possibly an artefact of scattering. These variations are typically two orders of magnitude smaller than that observed at 1400 MHz by Noutsos et al. (2009), for a different sample of southern pulsars. In this paper we present a possible explanation for the difference in magnitude of this effect between the two frequencies, based on scattering. Finally, we have estimated the magnetospheric emission heights of low-frequency radiation from four pulsars, based on the phase lags between the flux-density and the PA profiles, and the theoretical framework of Blaskiewicz et al. (1991, ApJ, 370, 643). These estimates yielded heights of a few hundred km; at least for PSR B1133+16, this is consistent with emission heights derived based on radius-to-frequency mapping, but is up to a few times larger than the recent upper limit based on pulsar timing.
Conclusions: Our work has shown that models, like magnetospheric birefringence, cannot be the sole explanation for the complex polarisation behaviour of pulsars. On the other hand, we have reinforced the claim that interstellar scattering can introduce a rotation of the PA with frequency that is indistinguishable from Faraday rotation and also varies as a function of pulse phase. In one case, the derived emission heights appear to be consistent with the predictions of radius-to-frequency mapping at 150 MHz, although this interpretation is subject to a number of systematic uncertainties
The LOFAR pilot surveys for pulsars and fast radio transients
We have conducted two pilot surveys for radio pulsars and fast transients
with the Low-Frequency Array (LOFAR) around 140 MHz and here report on the
first low-frequency fast-radio burst limit and the discovery of two new
pulsars. The first survey, the LOFAR Pilot Pulsar Survey (LPPS), observed a
large fraction of the northern sky, ~1.4 x 10^4 sq. deg, with 1-hr dwell times.
Each observation covered ~75 sq. deg using 7 independent fields formed by
incoherently summing the high-band antenna fields. The second pilot survey, the
LOFAR Tied-Array Survey (LOTAS), spanned ~600 sq. deg, with roughly a 5-fold
increase in sensitivity compared with LPPS. Using a coherent sum of the 6 LOFAR
"Superterp" stations, we formed 19 tied-array beams, together covering 4 sq.
deg per pointing. From LPPS we derive a limit on the occurrence, at 142 MHz, of
dispersed radio bursts of 107 Jy
for the narrowest searched burst duration of 0.66 ms. In LPPS, we re-detected
65 previously known pulsars. LOTAS discovered two pulsars, the first with LOFAR
or any digital aperture array. LOTAS also re-detected 27 previously known
pulsars. These pilot studies show that LOFAR can efficiently carry out all-sky
surveys for pulsars and fast transients, and they set the stage for further
surveying efforts using LOFAR and the planned low-frequency component of the
Square Kilometer Array.Comment: 18 pages, 10 figures, accepted for A&
Scattering analysis of LOFAR pulsar observations
We measure the effects of interstellar scattering on average pulse profiles from 13 radio pulsars with simple pulse shapes. We use data from the LOFAR High Band Antennas, at frequencies between 110 and 190 MHz.We apply a forward fitting technique, and simultaneously determine the intrinsic pulse shape, assuming single Gaussian component profiles. We find that the constant τ , associated with scattering by a single thin screen, has a power-law dependence on frequency τ ∝ ν -a , with indices ranging from α = 1.50 to 4.0, despite simplest theoretical models predicting α =4.0 or 4.4. Modelling the screen as an isotropic or extremely anisotropic scatterer, we find anisotropic scattering fits lead to larger power-law indices, often in better agreement with theoretically expected values.We compare the scattering models based on the inferred, frequency-dependent parameters of the intrinsic pulse, and the resulting correction to the dispersion measure (DM). We highlight the cases in which fits of extreme anisotropic scattering are appealing, while stressing that the data do not strictly favour either model for any of the 13 pulsars. The pulsars show anomalous scattering properties that are consistent with finite scattering screens and/or anisotropy, but these data alone do not provide the means for an unambiguous characterization of the screens. We revisit the empirical t versus DM relation and consider how our results support a frequency dependence of a. Very long baseline interferometry, and observations of the scattering and scintillation properties of these sources at higher frequencies, will provide further evidence
Wide-band Simultaneous Observations of Pulsars: Disentangling Dispersion Measure and Profile Variations
20 Pages, 14 Figures, Accepted for publication in Astronomy & AstrophysicsInternational audienceDispersion in the interstellar medium is a well known phenomenon that follows a simple relationship, which has been used to predict the time delay of dispersed radio pulses since the late 1960s. We performed wide-band simultaneous observations of four pulsars with LOFAR (at 40-190 MHz), the 76-m Lovell Telescope (at 1400 MHz) and the Effelsberg 100-m Telescope (at 8000 MHz) to test the accuracy of the dispersion law over a broad frequency range. In this paper we present the results of these observations which show that the dispersion law is accurate to better than 1 part in 100000 across our observing band. We use this fact to constrain some of the properties of the ISM along the line-of-sight and use the lack of any aberration or retardation effects to determine upper limits on emission heights in the pulsar magnetosphere. We also discuss the effect of pulse profile evolution on our observations, and the implications that it could have for precision pulsar timing projects such as the detection of gravitational waves with pulsar timing arrays
Pulse profiles of 100 radio pulsars
The observed sample of pulsars was loosely based on a selection of the brightest objects in the LOFAR-visible sky (declination >-30°), using the ATNF Pulsar Catalog1 (Manchester et al., 2005AJ....129.1993M) for guidance. We observed 100 pulsars using the high-band antennas (HBAs) in the six central "Superterp" stations (CS002-CS007) of the LOFAR core. (3 data files)
Differential frequency-dependent delay from the pulsar magnetosphere
<p>Some radio pulsars show clear "drifting subpulses", in which subpulses are seen to drift in pulse longitude in a systematic pattern. Here we examine how the drifting subpulses of PSR B0809+74 evolve with time and observing frequency. We show that the subpulse period (P-3) is constant on timescales of days, months and years, and between 14-5100 MHz. Despite this, the shapes of the driftbands change radically with frequency. Previous studies have concluded that, while the subpulses appear to move through the pulse window approximately linearly at low frequencies (820 MHz) near to the peak of the average pulse profile. We use LOFAR, GMRT, GBT, WSRT and Effelsberg 100-m data to explore the frequency-dependence of this phase step. We show that the size of the subpulse phase step increases gradually, and is observable even at low frequencies. We attribute the subpulse phase step to the presence of two separate driftbands, whose relative arrival times vary with frequency - one driftband arriving 30 pulses earlier at 20 MHz than it does at 1380 MHz, whilst the other arrives simultaneously at all frequencies. The drifting pattern which is observed here cannot be explained by either the rotating carousel model or the surface oscillation model, and could provide new insight into the physical processes happening within the pulsar magnetosphere.</p>