Establishes sharp low-degree estimation thresholds in planted hypergraphs and tensor PCA, resolving open hardness questions and yielding polynomial-time algorithms above thresholds.
Detection Is Harder Than Estimation in Certain Regimes: Inference for Moment and Cumulant Tensors
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abstract
We study estimation and detection of high-order moment and cumulant tensors from $n$ i.i.d.\ observations of a $p$-dimensional random vector, with performance measured in tensor spectral norm. Under sub-Gaussianity, we show that the minimax rate for estimating the order-$d$ moment and cumulant tensors is $\sqrt{p/n}\wedge 1$. In contrast to covariance estimation, the sample moment tensor is generally not rate-optimal for $d\ge 3$, and we construct an estimator that attains the minimax rate up to logarithmic factors. On the computational side, we study testing whether the $d$-th order cumulant tensor vanishes after whitening. Using the low-degree polynomial framework, we provide evidence that detection is computationally hard when $n\ll p^{d/2}$. At the same time, we identify a regime in which an efficiently computable estimator achieves error smaller than the separation at which low-degree tests can reliably distinguish the null from the alternative. This reveals an unusual reverse detection--estimation gap: computationally efficient detection can be harder than computationally efficient estimation. The underlying reason is that the relevant loss, tensor spectral norm, is itself NP-hard to compute, creating a new form of computational--statistical gap.
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math.ST 1years
2026 1verdicts
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Low-degree estimation thresholds in planted hypergraphs and tensor PCA
Establishes sharp low-degree estimation thresholds in planted hypergraphs and tensor PCA, resolving open hardness questions and yielding polynomial-time algorithms above thresholds.