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arxiv: 2106.15908 · v1 · pith:OFNNSFQJnew · submitted 2021-06-30 · 🧮 math.ST · math.PR· stat.TH

A Statistical Taylor Theorem and Extrapolation of Truncated Densities

classification 🧮 math.ST math.PRstat.TH
keywords samplestheoremtruncatedapproximationdensitydistributionestimationnon-parametric
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We show a statistical version of Taylor's theorem and apply this result to non-parametric density estimation from truncated samples, which is a classical challenge in Statistics \cite{woodroofe1985estimating, stute1993almost}. The single-dimensional version of our theorem has the following implication: "For any distribution $P$ on $[0, 1]$ with a smooth log-density function, given samples from the conditional distribution of $P$ on $[a, a + \varepsilon] \subset [0, 1]$, we can efficiently identify an approximation to $P$ over the \emph{whole} interval $[0, 1]$, with quality of approximation that improves with the smoothness of $P$." To the best of knowledge, our result is the first in the area of non-parametric density estimation from truncated samples, which works under the hard truncation model, where the samples outside some survival set $S$ are never observed, and applies to multiple dimensions. In contrast, previous works assume single dimensional data where each sample has a different survival set $S$ so that samples from the whole support will ultimately be collected.

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