Detection of Correlated Random Vectors
This addresses a fundamental hypothesis testing problem in statistics and information theory, with potential applications in signal processing and data analysis, though it appears incremental in extending to multi-dimensional generalizations.
The paper tackles the problem of detecting correlation between two standard normal random vectors, analyzing thresholds for optimal testing as a function of vector dimension and correlation strength, and finds information-theoretic limits with a novel technique revealing connections to integer partition functions.
In this paper, we investigate the problem of deciding whether two standard normal random vectors $\mathsf{X}\in\mathbb{R}^{n}$ and $\mathsf{Y}\in\mathbb{R}^{n}$ are correlated or not. This is formulated as a hypothesis testing problem, where under the null hypothesis, these vectors are statistically independent, while under the alternative, $\mathsf{X}$ and a randomly and uniformly permuted version of $\mathsf{Y}$, are correlated with correlation $ρ$. We analyze the thresholds at which optimal testing is information-theoretically impossible and possible, as a function of $n$ and $ρ$. To derive our information-theoretic lower bounds, we develop a novel technique for evaluating the second moment of the likelihood ratio using an orthogonal polynomials expansion, which among other things, reveals a surprising connection to integer partition functions. We also study a multi-dimensional generalization of the above setting, where rather than two vectors we observe two databases/matrices, and furthermore allow for partial correlations between these two.