English

Dependency Network-Based Portfolio Design with Forecasting and VaR Constraints

Portfolio Management 2025-07-29 v1 Econometrics Statistical Finance Machine Learning

Abstract

This study proposes a novel portfolio optimization framework that integrates statistical social network analysis with time series forecasting and risk management. Using daily stock data from the S&P 500 (2020-2024), we construct dependency networks via Vector Autoregression (VAR) and Forecast Error Variance Decomposition (FEVD), transforming influence relationships into a cost-based network. Specifically, FEVD breaks down the VAR's forecast error variance to quantify how much each stock's shocks contribute to another's uncertainty information we invert to form influence-based edge weights in our network. By applying the Minimum Spanning Tree (MST) algorithm, we extract the core inter-stock structure and identify central stocks through degree centrality. A dynamic portfolio is constructed using the top-ranked stocks, with capital allocated based on Value at Risk (VaR). To refine stock selection, we incorporate forecasts from ARIMA and Neural Network Autoregressive (NNAR) models. Trading simulations over a one-year period demonstrate that the MST-based strategies outperform a buy-and-hold benchmark, with the tuned NNAR-enhanced strategy achieving a 63.74% return versus 18.00% for the benchmark. Our results highlight the potential of combining network structures, predictive modeling, and risk metrics to improve adaptive financial decision-making.

Keywords

Cite

@article{arxiv.2507.20039,
  title  = {Dependency Network-Based Portfolio Design with Forecasting and VaR Constraints},
  author = {Zihan Lin and Haojie Liu and Randall R. Rojas},
  journal= {arXiv preprint arXiv:2507.20039},
  year   = {2025}
}
R2 v1 2026-07-01T04:20:24.900Z