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Autores principales: Yang, Liusha, Zhao, Siqi, Chai, Shuqi
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2601.15597
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author Yang, Liusha
Zhao, Siqi
Chai, Shuqi
author_facet Yang, Liusha
Zhao, Siqi
Chai, Shuqi
contents This paper introduces a neural network-based nonlinear shrinkage estimator of covariance matrices for the purpose of minimum variance portfolio optimization. It is a hybrid approach that integrates statistical estimation with machine learning. Starting from the Ledoit-Wolf (LW) shrinkage estimator, we decompose the LW covariance matrix into its eigenvalues and eigenvectors, and apply a lightweight transformer-based neural network to learn a nonlinear eigenvalue shrinkage function. Trained with portfolio risk as the loss function, the resulting precision matrix (the inverse covariance matrix) estimator directly targets portfolio risk minimization. By conditioning on the sample-to-dimension ratio, the approach remains scalable across different sample sizes and asset universes. Empirical results on stock daily returns from Standard & Poor's 500 Index (S&P500) demonstrate that the proposed method consistently achieves lower out-of-sample realized risk than benchmark approaches. This highlights the promise of integrating structural statistical models with data-driven learning.
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publishDate 2026
record_format arxiv
spellingShingle Neural Nonlinear Shrinkage of Covariance Matrices for Minimum Variance Portfolio Optimization
Yang, Liusha
Zhao, Siqi
Chai, Shuqi
Machine Learning
Signal Processing
This paper introduces a neural network-based nonlinear shrinkage estimator of covariance matrices for the purpose of minimum variance portfolio optimization. It is a hybrid approach that integrates statistical estimation with machine learning. Starting from the Ledoit-Wolf (LW) shrinkage estimator, we decompose the LW covariance matrix into its eigenvalues and eigenvectors, and apply a lightweight transformer-based neural network to learn a nonlinear eigenvalue shrinkage function. Trained with portfolio risk as the loss function, the resulting precision matrix (the inverse covariance matrix) estimator directly targets portfolio risk minimization. By conditioning on the sample-to-dimension ratio, the approach remains scalable across different sample sizes and asset universes. Empirical results on stock daily returns from Standard & Poor's 500 Index (S&P500) demonstrate that the proposed method consistently achieves lower out-of-sample realized risk than benchmark approaches. This highlights the promise of integrating structural statistical models with data-driven learning.
title Neural Nonlinear Shrinkage of Covariance Matrices for Minimum Variance Portfolio Optimization
topic Machine Learning
Signal Processing
url https://arxiv.org/abs/2601.15597