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Integrating multiple sources of ordinal information in portfolio optimization

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  • Eranda c{C}ela
  • Stephan Hafner
  • Roland Mestel
  • Ulrich Pferschy

Abstract

Active portfolio management tries to incorporate any source of meaningful information into the asset selection process. In this contribution we consider qualitative views specified as total orders of the expected asset returns and discuss two different approaches for incorporating this input in a mean-variance portfolio optimization model. In the robust optimization approach we first compute a posterior expectation of asset returns for every given total order by an extension of the Black-Litterman (BL) framework. Then these expected asset returns are considered as possible input scenarios for robust optimization variants of the mean-variance portfolio model (max-min robustness, min regret robustness and soft robustness). In the order aggregation approach rules from social choice theory (Borda, Footrule, Copeland, Best-of-k and MC4) are used to aggregate the total order in a single ``consensus total order''. Then expected asset returns are computed for this ``consensus total order'' by the extended BL framework mentioned above. Finally, these expectations are used as an input of the classical mean-variance optimization. Using data from EUROSTOXX 50 and S&P 100 we empirically compare the success of the two approaches in the context of portfolio performance analysis and observe that in general aggregating orders by social choice methods outperforms robust optimization based methods for both data sets.

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  • Eranda c{C}ela & Stephan Hafner & Roland Mestel & Ulrich Pferschy, 2022. "Integrating multiple sources of ordinal information in portfolio optimization," Papers 2211.00420, arXiv.org, revised Jul 2023.
    • Handle: RePEc:arx:papers:2211.00420
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    References listed on IDEAS

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