Large Volatility Matrix Prediction using Tensor Factor Structure
Abstract
Several approaches for predicting large volatility matrices have been developed based on high-dimensional factor-based It\^o processes. These methods often impose restrictions to reduce the model complexity, such as constant eigenvectors or factor loadings over time. However, several studies indicate that eigenvector processes are also time-varying. To address this feature, this paper generalizes the factor structure by representing the integrated volatility matrix process as a cubic (order-3 tensor) form, which is decomposed into low-rank tensor and idiosyncratic tensor components. To predict conditional expected large volatility matrices, we propose the Projected Tensor Principal Orthogonal componEnt Thresholding (PT-POET) procedure and establish its asymptotic properties. The advantages of PT-POET are validated through a simulation study and demonstrated in an application to minimum variance portfolio allocation using high-frequency trading data.
Keywords
Cite
@article{arxiv.2412.04293,
title = {Large Volatility Matrix Prediction using Tensor Factor Structure},
author = {Sung Hoon Choi and Donggyu Kim},
journal= {arXiv preprint arXiv:2412.04293},
year = {2025}
}