|InterJournal Complex Systems, 2229
|Manuscript Number: |
Submission Date: 20080226
|Computational Intelligence in Financial Contagion Analysis|
Problem: Over the past two decades, financial market crises have occurred in different regions and revealed a unifying characteristic. Whether the crisis is in Mexico, Asia, or Russia, the financial difficulties from one economy spread to neighbouring economies in the region. If the difficulties are spread through stable cross-market linkages, then the country experiencing the original shock can take measures improving the fundamentals. If the shocks are propagated although the fundamentals are sound, then an IMF intervention will be appropriate. Unstable cross-market linkages during financial crises are referred to as financial contagion. Financial contagion has been studied intensively in recent years, focusing on the definition and the statistical measuring of the phenomenon, and the ex-post investigation of crisis data for the existence of contagion. Alternatively, we consider here simulating financial markets and linkages through modelling market participants and their various strategies. Modifying the agents’ behaviours and evolving linked markets will allow testing for financial contagion under various scenarios. Methods: We develop an agent-based model and investigate herding behaviours as a reason for contagion. Participants in financial markets are divided as smart traders and noise traders. Smart traders make decisions based on fundamental or technical analysis, while noise traders contribute to herding behaviours. The starting point is a linked-market model based on statistical mechanics, with varying ratios of smart vs. noise traders in each market. To be able to study more realistic strategies, we develop the model further implementing a minority game approach. Results: Various strategies and simulation parameters are able to divide agents into different types. We also explore different parameters and market characteristics. Through introducing shocks to one of the markets, the investigation is focused on the simulations which present evidence for financial contagion. Conclusions: Though a problem of current interest, financial contagion has not been studied using computational intelligence techniques. It is a phenomenon occurring through the function and linkages of financial markets as complex systems, and should be approached using the range of methodologies available within the complex systems paradigm. Investigating the characteristics of the simulations leading to financial contagion, will contribute to recognising at an earlier stage financial crises which potentially destabilise cross-market linkages. In the real world, such information would be valuable in enabling appropriate risk management actions. 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