Improved AGN light curve analysis with the z-transformed discrete correlation function

Alexander, Tal

Improved AGN light curve analysis with the z-transformed discrete correlation function

Tal Alexander
(
- Weizmann Inst.
)

Feb 6, 2013

20 pages

e-Print:

1302.1508 [astro-ph.IM]

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Abstract: (arXiv)

The cross-correlation function (CCF) is commonly employed in the study of AGN, where it is used to probe the structure of the broad line region by line reverberation, to study the continuum emission mechanism by correlating multi-waveband light curves and to seek correlations between the variability and other AGN properties. The z -transformed discrete correlation function (ZDCF) is a new method for estimating the CCF of sparse, unevenly sampled light curves. Unlike the commonly used interpolation method, it does not assume that the light curves are smooth and it does provide errors on its estimates. The ZDCF corrects several biases of the discrete correlation function method of Edelson & Krolik (1988) by using equal population binning and Fisher's z -transform. These lead to a more robust and powerful method of estimating the CCF of sparse light curves of as few as 12 points. Two examples of light curve analysis with the ZDCF are presented. 1) The ZDCF estimate of the auto-correlation function is used to uncover a correlation between AGN magnitude and variability time scale in a small simulated sample of very sparse and irregularly sampled light curves. 2) A maximum likelihood function for the ZDCF peak location is used to estimate the time-lag between two light curves. Fortran 77 and 95 code implementations of the ZDCF and the maximum likelihood peak location (PLIKE) algorithms are freely available (see http://www.weizmann.ac.il/weizsites/tal/research/software/).

Note:

An expanded description of the ZDCF and PLIKE algorithms (http://www.weizmann.ac.il/weizsites/tal/research/software), posted on astro-ph following requests by users (see main reference: Alexander 1997 "Is AGN Variability Correlated with Other AGN Properties? ZDCF Analysis of Small Samples of Sparse Light Curves" http://adsabs.harvard.edu/abs/1997ASSL..218..163A)

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