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Portfolio choice under cumulative prospect theory: sensitivity analysis and an empirical study

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Abstract

A sensitivity analysis of the impact of cumulative prospect theory (CPT) parameters on a Mean/Risk efficient frontier is performed through a simulation procedure, assuming a Multivariate Variance Gamma distribution for log-returns. The optimal investment problem for an agent with CPT preferences is then investigated empirically, by considering different parameters’ combinations for the CPT utility function. Three different portfolios, one hedge fund and two equity portfolios are considered in this study, where the Modified Herfindahl index is used as a measure of portfolio diversification, while the Omega ratio and the Information ratio are used as measures of performance.

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Notes

  1. One of the main assumptions of EU theory is the independence axiom, which states that the intrinsic value that an individual places on any particular outcome in a gamble will not be influenced by the other possible outcomes (either within that gamble or within other gambles to which the gamble is being compared), or by the size of the probability of the outcome occurring. The axiom requires that, when comparing gambles, all common outcomes that have the same probability of occurring will be viewed by the individual as irrelevant. In a famous criticism of EU, Maurice Allais argued that under certain conditions individuals will systematically violate independence. Allais proposition is known as the Allais paradox (or the common consequence effect), and has been empirically supported in subsequent analysis [see, among the others (Morrison 1967; MacCrimmon and Larsson 1979; Kahneman and Tversky 1979; Camerer and Kunreuther 1989)].

  2. Omega Ratio is defined by:

    $$\begin{aligned} \varOmega =\frac{\mathbb {E}\left( R_P-\tau \right) ^+}{\mathbb {E}\left( \tau -R_P\right) ^+}, \end{aligned}$$

    where \(R_P\) denotes the return of the portfolio and \(\tau \) is a specified threshold. \(\varOmega \) ratio is very sensitive to \(\tau \), which can be different from investor to investor. In the empirical analysis \(\tau \) is set equal to 0. For a given threshold, a higher ratio indicates that the portfolio provides more expected gains than expected losses and so it would be preferred by an investor.

  3. In case of mean-variance portfolio the considered risk aversion parameter is one.

  4. Here \(X_p\) indicates the portfolio return. The use of a B-spline interpolation to deal with non-smoothness and non differentiability is not a new idea in finance [see (Potaptchik et al. 2008; Grüne and Semmler 2004) and the references therein].

  5. For more information on the Global Search algorithm see. http://it.mathworks.com/help/gads/how-globalsearch-and-multistart-work.html.

  6. The finer the grid is, the more precise the solution is, and the longer the computation time will be.

  7. Given the first four moments of each asset and the corresponding correlation matrix, we implement an algorithm able to estimate the parameters of the MVG distribution (see Hitaj and Mercuri 2013a, b). We then simulate a sample of \(10^4\) observations for the log-returns by means of the MVG r.v. with the desired parameters. The reason for using the MVG to simulate assets’ returns is related to the fact that this distribution can capture some of the stylized facts of assets’ returns (see Hitaj and Mercuri 2013b and the references therein).

  8. Loss aversion implies, for example, that one who loses one hundred dollars will lose more satisfaction than that gained from one hundred dollars windfall.

  9. The greater \(\beta \in (0,1)\), the lower the attitude to risk in losses.

  10. The data set is taken from www.hedgefundresearch.com.

  11. The data set for the second and third portfolios is downloaded from Bloomberg.

  12. The optimal portfolio is obtained by solving problem (8) for a CPT investor [or by solving for the GMV or the MV portfolio considering as feasible region (5)].

  13. We refer to the in-sample period also as 1 year (or 6 months).

  14. We refer to the out-of-sample period also as 1 week (or 1 month).

  15. More details about the results concerning the JB test for sub-samples are omitted for space constraints, but they are available upon request for the interested reader.

  16. The fact the MV portfolio is concentrated is due to the value of the risk aversion, which is fixed at 1. The level of risk aversion has an important impact on the portfolio (see Hitaj and Zambruno (2016) where a detailed analysis has been performed in case of a CARA utility function). Considering different levels of risk aversion goes beyond the objective of this paper.

  17. For space constraints the results obtained for the two equity portfolios are not reported, but are available upon author request.

  18. Of course each portfolio manager has his own reference portfolio. The reason for choosing the \(\textit{GMV}\) is that, when dealing with \(\mu /\sigma \) efficient frontier, it exhibits the minimum risk (\(\sigma \)).

  19. We point out that \(\varOmega \) ratio is very sensitive to \(\tau \) which can be different from investor to investor. In this analysis \(\tau \) is set equal to 0.

  20. Rolling window ‘1 year—1 week’ means that the in-sample period is 1 year and the out-of-sample period is 1 week.

  21. For space constraints the results obtained in case of the other three rolling window strategies are not reported, but can be obtained from the authors upon request.

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Acknowledgements

The authors would like to thank the Editor and the anonymous Referees for their helpful comments. All remaining errors are responsibility of the authors. Asmerilda Hitaj and Elisa Mastrogiacomo want to acknowledge GNAPMA for the financial support of the project ’Levy processes, stochastic control and portfolio optimization’.

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Appendix

Appendix

In the following the results obtained for the two equity portfolios under analysis are reported.

1.1 Equity portfolio 1 results

See Tables 3, 4 and Figs. 6, 7.

Table 3 Annual descriptive statistics for the equity portfolio 1
Table 4 Equity portfolio 1: percentage when the loss in terms of Information Ratio (having as benchmark the Global Minimum Variance portfolio) of the CPT portfolios, is statistically significant different from 0, for the 4 rolling-window strategies considered and different levels of significance
Fig. 6
figure 6

Equity portfolio 1 in case of rolling-window 1 year (250 days)—1 week (5 days). The figure is divided in 6 sectors, one for each level of \(\alpha \). On the x-axis the value of \(\beta \) is indicated; each point in the figure is associated with a number that indicates the value of \(\lambda \). On the y-axis the value of the average out-of-sample Information Ratio (with respect to the GMV portfolio) for a particular combination of parameters is reported. It is evident that the Information Ratio in the majority of the cases under consideration is less than zero meaning that, in an out-of-sample perspective, the CPT portfolios lead to a loss with respect to the GMV one

Fig. 7
figure 7

Equity portfolio 1; Rolling-window 1 year—1 week. The figure is divided in 6 parts, one for each level of \(\alpha \). On the x-axis the value of \(\beta \) is indicated; each point in the figure is associated with a number that indicates the value of \(\lambda \). On the y-axis the value of the average out-of-sample monthly Omega Ratio for different levels of \(\alpha \), \(\beta \) and \(\lambda \) is reported. The point labelled \(\textit{MV}\) indicates the result obtained from the Mean Variance model and the one labeled \(\textit{GMV}\) indicates the result obtained using the Global Minimum Variance

1.2 Equity portfolio 2 results

See Tables 5, 6 and Figs. 8, 9.

Table 5 Annual descriptive statistics for the components of equity portfolio 2
Table 6 Equity portfolio 2: percentage when the Information Ratio of the CPT portfolios, having as benchmark the Global Minimum Variance portfolio, is statistically significant different from 0, for the 4 rolling-window strategies considered and different levels of significance
Fig. 8
figure 8

Equity portfolio 2: rolling-window 1 year (250 days)—1 week (5 days). The figure is divided in 6 parts, one for each level of \(\alpha \). On the x-axis the value of \(\beta \) is indicated; each point in the figure is associated with a number that indicates the value of \(\lambda \). On the y-axis the value of the average out-of-sample Information Ratio (with respect to the GMV portfolio) for a particular combination of parameters is reported. Having always an Information Ratio greater than zero means that, in an out-of-sample perspective, the CPT model leads to a gain with respect to the GMV

Fig. 9
figure 9

Equity portfolio 2: rolling-window 1 year—1 week. The figure is divided in 6 parts, one for each level of \(\alpha \). On the x-axis the value of \(\beta \) is indicated; each point in the figure is associated with a number that indicates the value of \(\lambda \). On the y-axis the value of the average out-of-sample monthly Omega Ratio for different levels of \(\alpha \), \(\beta \) and \(\lambda \) is reported. The point labeled \(\textit{MV}\) indicates the result obtained from the Mean Variance model and the one labeled \(\textit{GMV}\) indicates the result obtained using the Global Minimum Variance. It is evident that in an out-of-sample the majority of the CPT portfolios lead to gains, in terms of Omega Ratio, with respect to the GMV and to the MV ones

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Consigli, G., Hitaj, A. & Mastrogiacomo, E. Portfolio choice under cumulative prospect theory: sensitivity analysis and an empirical study. Comput Manag Sci 16, 129–154 (2019). https://doi.org/10.1007/s10287-018-0333-x

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