Analytical and statistical properties of local depth functions motivated by clustering applications
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Local depth functions (LDFs) are used for describing the local geometric features of multivariate distributions, especially in multimodal models. In this paper, we undertake a rigorous systematic study of the LDFs and use it to develop a theoretically validated algorithm for clustering. For this reason, we establish several analytical and statistical properties of LDFs. First, we show that, when the underlying probability distribution is absolutely continuous, under an appropriate scaling that converge to zero (referred to as extreme localization), LDFs converge uniformly to a power of the density and obtain a related rate of convergence result. Second, we establish that the centered and scaled sample LDFs converge in distribution to a centered Gaussian process, uniformly in the space of bounded functions on R p x [0,infinity], as the sample size diverges to infinity. Third, under an extreme localization that depends on the sample size, we determine the correct centering and scaling for the sample LDFs to possess a limiting normal distribution. Fourth, invoking the above results, we develop a new clustering algorithm that uses the LDFs and their differentiability properties. Fifth, for the last purpose, we establish several results concerning the gradient systems related to LDFs. Finally, we illustrate the finite sample performance of our results using simulations and apply them to two datasets.
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