Yuefeng Si scite author profile

Estimating the structures at high or low quantiles has become an important subject and attracted increasing attention across numerous fields. However, due to data sparsity at tails, it usually is a challenging task to obtain reliable estimation, especially for high-dimensional data. This paper suggests a flexible parametric structure to tails, and this enables us to conduct the estimation at quantile levels with rich observations and then to extrapolate the fitted structures to far tails.The proposed model depends on some quantile indices and hence is called the quantile index regression. Moreover, the composite quantile regression method is employed to obtain non-crossing quantile estimators, and this paper further establishes their theoretical properties, including asymptotic normality for the case with low-dimensional covariates and non-asymptotic error bounds for that with highdimensional covariates. Simulation studies and an empirical example are presented to illustrate the usefulness of the new model.

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A new nonparametric extension of ANOVA via projection mean variance measure

Liu¹,

Si²,

Xu³

et al. 2022

STAT SINICA

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In this paper, we introduce a novel projection mean variance (PMV) measure to construct a nonparametric test for the multisample hypothesis of equal distributions for univariate or multivariate responses. The proposed PMV measure generalizes the mean variance index via the projection technique. We obtain the theoretical properties of the PMV measure and its empirical counterpart. The PMV measure can yield an analogous variance component decomposition. Through this decomposition, an ANOVA F statistic is derived to test the multisample problem. The proposed test is statistically consistent against the general alternatives and robust to heavy-tailed data. The test is free of tuning parameters and does not require moment conditions on the response. The simulation results demonstrate that the PMV test has higher power than the classical Wilks-type

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An efficient tensor regression for high-dimensional data

Si¹,

Zhang²,

Li³

2022

Preprint

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Most currently used tensor regression models for high-dimensional data are based on Tucker decomposition, which has good properties but loses its efficiency in compressing tensors very quickly as the order of tensors increases, say greater than four or five. However, for the simplest tensor autoregression in handling time series data, its coefficient tensor already has the order of six. This paper revises a newly proposed tensor train (TT) decomposition and then applies it to tensor regression such that a nice statistical interpretation can be obtained. The new tensor regression can well match the data with hierarchical structures, and it even can lead to a better interpretation for the data with factorial structures, which are supposed to be better fitted by models with Tucker decomposition. More importantly, the new tensor regression can be easily applied to the case with higher order tensors since TT decomposition can compress the coefficient tensors much more efficiently. The methodology is also extended to tensor autoregression for time series data, and nonasymptotic properties are derived for the ordinary least squares estimations of both tensor regression and autoregression. A new algorithm is introduced to search for estimators, and its theoretical justification is also discussed. Theoretical and computational properties of the proposed methodology are verified by simulation studies, and the advantages over existing methods are illustrated by two real examples.

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Projection quantile correlation and its use in high-dimensional grouped variable screening

Liu

Niu

et al. 2022

Computational Statistics & Data Analysis

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A New Measure of Model Redundancy for Compressed Convolutional Neural Networks

Huang¹,

Si²,

Zheng³

et al. 2021

Preprint

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While recently many designs have been proposed to improve the model efficiency of convolutional neural networks (CNNs) on a fixed resource budget, theoretical understanding of these designs is still conspicuously lacking. This paper aims to provide a new framework for answering the question: Is there still any remaining model redundancy in a compressed CNN? We begin by developing a general statistical formulation of CNNs and compressed CNNs via the tensor decomposition, such that the weights across layers can be summarized into a single tensor. Then, through a rigorous sample complexity analysis, we reveal an important discrepancy between the derived sample complexity and the naive parameter counting, which serves as a direct indicator of the model redundancy. Motivated by this finding, we introduce a new model redundancy measure for compressed CNNs, called the K/R ratio, which further allows for nonlinear activations. The usefulness of this new measure is supported by ablation studies on popular block designs and datasets.

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Yuefeng Si

Quantile index regression

A new nonparametric extension of ANOVA via projection mean variance measure

An efficient tensor regression for high-dimensional data

Projection quantile correlation and its use in high-dimensional grouped variable screening

A New Measure of Model Redundancy for Compressed Convolutional Neural Networks

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