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124 lines
6.3 KiB
Plaintext
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# HTRU2
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Author: Rob Lyon, School of Computer Science & Jodrell Bank Centre for Astrophysics,
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University of Manchester, Kilburn Building, Oxford Road, Manchester M13 9PL.
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Contact: rob@scienceguyrob.com or robert.lyon@.manchester.ac.uk
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Web: http://www.scienceguyrob.com or http://www.cs.manchester.ac.uk
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or alternatively http://www.jb.man.ac.uk
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1. Overview
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HTRU2 is a data set which describes a sample of pulsar candidates collected during the
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High Time Resolution Universe Survey (South) [1].
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Pulsars are a rare type of Neutron star that produce radio emission detectable here on
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Earth. They are of considerable scientific interest as probes of space-time, the inter-
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stellar medium, and states of matter (see [2] for more uses).
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As pulsars rotate, their emission beam sweeps across the sky, and when this crosses
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our line of sight, produces a detectable pattern of broadband radio emission. As pulsars
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rotate rapidly, this pattern repeats periodically. Thus pulsar search involves looking
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for periodic radio signals with large radio telescopes.
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Each pulsar produces a slightly different emission pattern, which varies slightly with each
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rotation (see [2] for an introduction to pulsar astrophysics to find out why). Thus a
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potential signal detection known as a 'candidate', is averaged over many rotations of the
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pulsar, as determined by the length of an observation. In the absence of additional info,
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each candidate could potentially describe a real pulsar. However in practice almost all
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detections are caused by radio frequency interference (RFI) and noise, making legitimate
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signals hard to find.
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Machine learning tools are now being used to automatically label pulsar candidates to
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facilitate rapid analysis. Classification systems in particular are being widely adopted,
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(see [4,5,6,7,8,9]) which treat the candidate data sets as binary classification problems.
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Here the legitimate pulsar examples are a minority positive class, and spurious examples
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the majority negative class. At present multi-class labels are unavailable, given the
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costs associated with data annotation.
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The data set shared here contains 16,259 spurious examples caused by RFI/noise, and 1,639
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real pulsar examples. These examples have all been checked by human annotators. Each
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candidate is described by 8 continuous variables. The first four are simple statistics
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obtained from the integrated pulse profile (folded profile). This is an array of continuous
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variables that describe a longitude-resolved version of the signal that has been averaged
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in both time and frequency (see [3] for more details). The remaining four variables are
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similarly obtained from the DM-SNR curve (again see [3] for more details). These are
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summarised below:
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1. Mean of the integrated profile.
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2. Standard deviation of the integrated profile.
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3. Excess kurtosis of the integrated profile.
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4. Skewness of the integrated profile.
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5. Mean of the DM-SNR curve.
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6. Standard deviation of the DM-SNR curve.
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7. Excess kurtosis of the DM-SNR curve.
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8. Skewness of the DM-SNR curve.
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HTRU 2 Summary
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17,898 total examples.
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1,639 positive examples.
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16,259 negative examples.
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The data is presented in two formats: CSV and ARFF (used by the WEKA data mining tool).
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Candidates are stored in both files in separate rows. Each row lists the variables first,
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and the class label is the final entry. The class labels used are 0 (negative) and 1
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(positive).
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Please not that the data contains no positional information or other astronomical details. It is
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simply feature data extracted from candidate files using the PulsarFeatureLab tool (see [10]).
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2. Citing our work
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If you use the dataset in your work please cite us using the DOI of the dataset, and the paper:
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R. J. Lyon, B. W. Stappers, S. Cooper, J. M. Brooke, J. D. Knowles, Fifty Years of Pulsar
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Candidate Selection: From simple filters to a new principled real-time classification approach
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MNRAS, 2016.
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3. Acknowledgements
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This data was obtained with the support of grant EP/I028099/1 for the University of Manchester
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Centre for Doctoral Training in Computer Science, from the UK Engineering and Physical Sciences
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Research Council (EPSRC). The raw observational data was collected by the High Time Resolution
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Universe Collaboration using the Parkes Observatory, funded by the Commonwealth of Australia and
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managed by the CSIRO.
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4. References
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[1] M.~J. Keith et al., "The High Time Resolution Universe Pulsar Survey - I. System Configuration
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and Initial Discoveries",2010, Monthly Notices of the Royal Astronomical Society, vol. 409,
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pp. 619-627. DOI: 10.1111/j.1365-2966.2010.17325.x
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[2] D. R. Lorimer and M. Kramer, "Handbook of Pulsar Astronomy", Cambridge University Press, 2005.
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[3] R. J. Lyon, "Why Are Pulsars Hard To Find?", PhD Thesis, University of Manchester, 2015.
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[4] R. J. Lyon et al., "Fifty Years of Pulsar Candidate Selection: From simple filters to a new
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principled real-time classification approach", Monthly Notices of the Royal Astronomical Society,
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submitted.
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[5] R. P. Eatough et al., "Selection of radio pulsar candidates using artificial neural networks",
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Monthly Notices of the Royal Astronomical Society, vol. 407, no. 4, pp. 2443-2450, 2010.
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[6] S. D. Bates et al., "The high time resolution universe pulsar survey vi. an artificial neural
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network and timing of 75 pulsars", Monthly Notices of the Royal Astronomical Society, vol. 427,
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no. 2, pp. 1052-1065, 2012.
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[7] D. Thornton, "The High Time Resolution Radio Sky", PhD thesis, University of Manchester,
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Jodrell Bank Centre for Astrophysics School of Physics and Astronomy, 2013.
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[8] K. J. Lee et al., "PEACE: pulsar evaluation algorithm for candidate extraction a software package
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for post-analysis processing of pulsar survey candidates", Monthly Notices of the Royal Astronomical
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Society, vol. 433, no. 1, pp. 688-694, 2013.
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[9] V. Morello et al., "SPINN: a straightforward machine learning solution to the pulsar candidate
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selection problem", Monthly Notices of the Royal Astronomical Society, vol. 443, no. 2,
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pp. 1651-1662, 2014.
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[10] R. J. Lyon, "PulsarFeatureLab", 2015, https://dx.doi.org/10.6084/m9.figshare.1536472.v1.
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