Deep Learning and High-Frequency Data Enhanced Bayesian Financial Risk Forecasting
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Open Access
Type
ThesisThesis type
Doctor of PhilosophyAbstract
This thesis, titled "Deep Learning and High-Frequency Data Enhanced Bayesian Financial Risk
Forecasting," presents an innovative approach in forecasting financial tail risks, particularly focusing
on Value-at-Risk (VaR) and Expected Shortfall (ES) through a Bayesian framework.
The ...
See moreThis thesis, titled "Deep Learning and High-Frequency Data Enhanced Bayesian Financial Risk Forecasting," presents an innovative approach in forecasting financial tail risks, particularly focusing on Value-at-Risk (VaR) and Expected Shortfall (ES) through a Bayesian framework. The first part of this thesis introduces a semi-parametric framework for joint VaR and ES forecasting, incorporating multiple realized measures such as realized variance, bi-power variation, and realized kernel. Extending the realized exponential GARCH model, this framework employs a quasi-likelihood function based on the asymmetric Laplace distribution, enabling Bayesian estimation through adaptive Markov Chain Monte Carlo methods. The second part advances risk forecasting further by proposing a long-memory and non-linear model, termed RNN-HAR, for direct VaR prediction. This model integrates a Recurrent Neural Network (RNN) with the heterogeneous autoregressive (HAR) model to capture long-memory effects and non-linear dependencies within realized volatility measures. Using loss-based Bayesian Sequential Monte Carlo (SMC) for inference, the RNN-HAR model demonstrates superior predictive performance outperforming conventional HAR models in VaR forecasting. The final part of the thesis proposes a novel RNN-based framework, RNN-ReESCAViaR, for the joint estimation of VaR and ES. By embedding an RNN within the Realized-ES-CAViaR (Conditional Autoregressive VaR) model and employing an asymmetric Laplace quasi-likelihood function, this framework captures the interdependence between VaR and ES in a highly flexible manner. Bayesian SMC is again utilized, enhancing computational efficiency and allowing for real-time sequential prediction. Empirical results show that RNN-ReESCAViaR achieves significant improvements over both parametric and semi-parametric models, illustrating its capacity to adapt to complex volatility patterns in financial data.
See less
See moreThis thesis, titled "Deep Learning and High-Frequency Data Enhanced Bayesian Financial Risk Forecasting," presents an innovative approach in forecasting financial tail risks, particularly focusing on Value-at-Risk (VaR) and Expected Shortfall (ES) through a Bayesian framework. The first part of this thesis introduces a semi-parametric framework for joint VaR and ES forecasting, incorporating multiple realized measures such as realized variance, bi-power variation, and realized kernel. Extending the realized exponential GARCH model, this framework employs a quasi-likelihood function based on the asymmetric Laplace distribution, enabling Bayesian estimation through adaptive Markov Chain Monte Carlo methods. The second part advances risk forecasting further by proposing a long-memory and non-linear model, termed RNN-HAR, for direct VaR prediction. This model integrates a Recurrent Neural Network (RNN) with the heterogeneous autoregressive (HAR) model to capture long-memory effects and non-linear dependencies within realized volatility measures. Using loss-based Bayesian Sequential Monte Carlo (SMC) for inference, the RNN-HAR model demonstrates superior predictive performance outperforming conventional HAR models in VaR forecasting. The final part of the thesis proposes a novel RNN-based framework, RNN-ReESCAViaR, for the joint estimation of VaR and ES. By embedding an RNN within the Realized-ES-CAViaR (Conditional Autoregressive VaR) model and employing an asymmetric Laplace quasi-likelihood function, this framework captures the interdependence between VaR and ES in a highly flexible manner. Bayesian SMC is again utilized, enhancing computational efficiency and allowing for real-time sequential prediction. Empirical results show that RNN-ReESCAViaR achieves significant improvements over both parametric and semi-parametric models, illustrating its capacity to adapt to complex volatility patterns in financial data.
See less
Date
2025Rights statement
The author retains copyright of this thesis. It may only be used for the purposes of research and study. It must not be used for any other purposes and may not be transmitted or shared with others without prior permission.Faculty/School
The University of Sydney Business School, Discipline of Business AnalyticsAwarding institution
The University of SydneyShare