Abstract
We investigate degree-degree correlations for scale-free graph sequences. The main conclusion of this paper is that the assortativity coefficient is not the appropriate way to describe degree-dependences in scale-free random graphs. Indeed, we study the infinite volume limit of the assortativity coefficient, and show that this limit is always non-negative when the degrees have finite first but infinite third moment, i.e., when the degree exponent $\gamma + 1$ of the density satisfies $\gamma \in (1,3)$. More generally, our results show that the correlation coefficient is inappropriate to describe dependencies between random variables having infinite variance. We start with a simple model of the sample correlation of random variables $X$ and $Y$, which are linear combinations with non-negative coefficients of the same infinite variance random variables. In this case, the correlation coefficient of $X$ and $Y$ is not defined, and the sample covariance converges to a proper random variable with support that is a subinterval of $(-1,1)$. Further, for any joint distribution $(X,Y)$ with equal marginals being non-negative power-law distributions with infinite variance (as in the case of degree-degree correlations), we show that the limit is non-negative. We next adapt these results to the assortativity in networks as described by the degree-degree correlation coefficient, and show that it is non-negative in the large graph limit when the degree distribution has an infinite third moment. We illustrate these results with several examples where the assortativity behaves in a non-sensible way. We further discuss alternatives for describing assortativity in networks based on rank correlations that are appropriate for infinite variance variables. We support these mathematical results by simulations.
Highlights
In this article we present an analytical study of degree-degree correlations in graphs with power-law degree distribution
We provide examples where in the Pearson’s correlation coefficient converges to zero in a network with strong negative degree-degree dependencies, and another example where this coefficient converges in distribution to a random variable
We have investigated dependency measures for power-law random variables
Summary
In this article we present an analytical study of degree-degree correlations in graphs with power-law degree distribution. A random variable X has a power-law distribution with tail exponent γ > 0 if its tail probability P (X > x) is roughly proportional to x−γ , for large enough x. Large selforganizing networks, such as the Internet, the World Wide Web, social, and biological networks, usually exhibit high variation in the values of the degrees. Such networks are called scale free indicating that there is no typical scale for the degrees, and the high-degree vertices are called hubs. One of them is how to measure dependencies between network parameters
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