AI-Assisted Analysis of Policy Communication during Economic Crises: Correlations with Market Confidence and Recovery Outcomes

Aixin Kang; Kai Zhang; Yuexing Chen

doi:10.71222/zds73g27

Authors

Aixin Kang Department of Economics, Georgetown University, DC, USA Author
Kai Zhang Department of Computer Science, Illinois institute of technology, IL, USA Author
Yuexing Chen Department of Computer Science, Illinois institute of technology, IL, USA Author

DOI:

https://doi.org/10.71222/zds73g27

Keywords:

policy communication analysis, economic crisis management, market confidence modeling, Flying Neural Network

Abstract

Economic crises necessitate effective policy communications to stabilize markets and facilitate recovery. This study introduces a novel multi-modal natural language processing (NLP) framework for analyzing policy communications during five major economic crises (2008-2009 Global Financial Crisis, 2010-2012 European Debt Crisis, 2015-2016 Commodity Crash, 2020 COVID-19 Downturn, and 2022-2023 Inflation Surge). The framework integrates the Flying Neural Network architecture — a novel neural model designed for dynamic pattern recognition — with reinforcement learning mechanisms to identify linguistic features influencing market confidence. Analysis of 14,297 official policy statements across seven major economies reveals significant correlations between communication characteristics and market confidence indicators. Commitment signaling emerges as the most influential linguistic feature (importance score 0.37), with maximum correlation strength occurring two days after the announcement (T + 2). Communications exhibiting high clarity indices (CI > 0.65) and moderate technical density (TD 0.30-0.45) demonstrated superior effectiveness in stabilizing market expectations. Temporal analysis indicates systematic variation in optimal communication strategies across crisis phases, with balanced approach communications generating most favorable recovery trajectories (average duration: 34.3 weeks). The reinforcement learning model achieves 83.7% directional forecast accuracy and 71.4% accuracy in recovery duration estimates. These findings advance the theoretical understanding of economic communication dynamics while providing actionable guidelines for optimizing policy communications during crisis periods.

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