A Robust Dynamic Matrix Factor Model for High-Dimensional Time Series with Heavy-Tailed Error Distributions

dc.contributor.advisorMcVinish, Ross
dc.contributor.authorAbu Shahin, Zainab Saeed A
dc.date.accessioned2026-02-08T06:28:55Z
dc.date.issued2026
dc.descriptionThis thesis investigates robust dynamic matrix factor models for high-dimensional time series with heavy-tailed error distributions. The proposed methodology combines theoretical analysis with simulation studies to establish consistency and asymptotic properties of the estimators. An empirical application to financial portfolio return data demonstrates the practical relevance and improved performance of the proposed approach.
dc.description.abstractHigh-dimensional time series analysis has become essential in modern data science, particularly in financial and economic applications where the number of variables often exceeds the available sample size. Classical Vector Autoregressive (VAR) models suffer from parameter explosion in such settings, while standard factor models may fail to capture intrinsic row--column interactions or accommodate non-Gaussian, heavy-tailed noise. This thesis studies a robust dynamic matrix factor model that preserves the matrix structure of the observations to achieve parsimonious dimension reduction, while modeling latent factor dynamics through a Matrix Autoregressive process of order one (MAR(1)). To address data contamination and heavy-tailed error distributions, the study develops and evaluates robust estimation methodologies, including Robust Matrix Factor Analysis (RMFA) and Iterative Huber Regression (IHR), which employ Huber-type loss functions to down-weight extreme observations. These approaches are contrasted with traditional spectral methods such as $\alpha$-PCA and Projected Estimation. Theoretical results establish consistency and asymptotic normality of the estimators under weaker moment conditions than those required for least-squares-based methods. Extensive simulation studies demonstrate that while spectral methods perform well under Gaussian noise, robust procedures deliver superior accuracy in loading space recovery and factor-rank determination under heavy-tailed environments. An empirical application to Fama--French $10 \times 10$ portfolio returns identifies a stable $(2,2)$ factor structure, highlighting both the robustness gains and the limitations of linear MAR(1) dynamics under extreme market shocks.
dc.format.extent131
dc.identifier.citationAbu Shahin, Zainab. (2026). A Robust Dynamic Matrix Factor Model for High-Dimensional Time Series with Heavy-Tailed Error Distributions. Master of Science thesis, The University of Queensland.
dc.identifier.urihttps://hdl.handle.net/20.500.14154/78102
dc.language.isoen
dc.publisherSaudi Digital Library
dc.subjectHigh-dimensional time series
dc.subjectMatrix factor models
dc.subjectDynamic matrix factor models
dc.subjectRobust estimation
dc.subjectHeavy-tailed distributions
dc.subjectMatrix autoregressive models
dc.subjectFactor rank determination
dc.subjectIterative Huber regression.
dc.titleA Robust Dynamic Matrix Factor Model for High-Dimensional Time Series with Heavy-Tailed Error Distributions
dc.typeThesis
sdl.degree.departmentSchool of Mathematics and Physics
sdl.degree.disciplineScience in Statistics
sdl.degree.grantorThe University of Queensland
sdl.degree.nameMaster of Science in Statistics
sdl.thesis.sourceSACM - Australia

Files

Original bundle

Now showing 1 - 1 of 1
No Thumbnail Available
Name:
SACM-Dissertation.pdf
Size:
2.38 MB
Format:
Adobe Portable Document Format

License bundle

Now showing 1 - 1 of 1
No Thumbnail Available
Name:
license.txt
Size:
1.61 KB
Format:
Item-specific license agreed to upon submission
Description:

Collections

Copyright owned by the Saudi Digital Library (SDL) © 2026