Dynamic mean variance asset allocation: Tests for robustness

We consider a portfolio consisting of a risk-free bond and an equity index which follows a jump diffusion process. Parameters for the inflation-adjusted return of the stock index and the risk-free bond are determined by examining 89 years of data. The optimal dynamic asset allocation strategy for a long-term pre-commitment mean variance (MV) investor is determined by numerically solving a Hamilton–Jacobi–Bellman partial integro-differential equation. The MV strategy is mathematically equivalent to minimizing the quadratic shortfall of the target terminal wealth. We incorporate realistic constraints on the strategy: discrete rebalancing (yearly), maximum leverage, and no trading if insolvent. Extensive synthetic market tests and resampled backtests of historical data indicate that the multi-period MV strategy achieves approximately the same expected terminal wealth as a constant weight strategy, but with much smaller variance and probability of shortfall.

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ROBUST ASSET ALLOCATION FOR LONG-TERM TARGET-BASED INVESTING

International Journal of Theoretical and Applied Finance ◽

10.1142/s0219024917500170 ◽

2017 ◽

Vol 20 (03) ◽

pp. 1750017 ◽

Cited By ~ 12

Author(s):

P. A. FORSYTH ◽

K. R. VETZAL

Keyword(s):

Standard Deviation ◽

Asset Allocation ◽

Optimal Strategy ◽

Stock Index ◽

Quadratic Loss ◽

Leverage Ratio ◽

Terminal Wealth ◽

Constant Proportion ◽

Mean Variance

This paper explores dynamic mean-variance (MV) asset allocation over long horizons. This is equivalent to target-based investing with a quadratic loss penalty for deviations from the target level of terminal wealth. We provide a number of illustrative examples in a setting with a risky stock index and a risk-free asset. Our underlying model is very simple: the value of the risky index is assumed to follow a geometric Brownian motion diffusion process and the risk-free interest rate is specified to be constant. We impose realistic constraints on the leverage ratio and trading frequency. In many of our examples, the MV optimal strategy has a standard deviation of terminal wealth less than half that of a constant proportion strategy which has the same expected value of terminal wealth, while the probability of shortfall is reduced by a factor of two to three. We investigate the robustness of the model through resampling experiments using historical data dating back to 1926. These experiments also show much lower standard deviation and shortfall probability for the MV optimal strategy relative to a constant proportion strategy with approximately the same expected terminal wealth.

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COMPARISON OF MEAN VARIANCE LIKE STRATEGIES FOR OPTIMAL ASSET ALLOCATION PROBLEMS

International Journal of Theoretical and Applied Finance ◽

10.1142/s0219024912500148 ◽

2012 ◽

Vol 15 (02) ◽

pp. 1250014 ◽

Cited By ~ 12

Author(s):

J. WANG ◽

P. A. FORSYTH

Keyword(s):

Asset Allocation ◽

Optimal Investment ◽

Quadratic Variation ◽

Investment Policy ◽

Investment Policies ◽

Efficient Frontiers ◽

Dynamic Investment ◽

Optimal Dynamic ◽

Hamilton Jacobi Bellman ◽

Mean Variance

We determine the optimal dynamic investment policy for a mean quadratic variation objective function by numerical solution of a nonlinear Hamilton-Jacobi-Bellman (HJB) partial differential equation (PDE). We compare the efficient frontiers and optimal investment policies for three mean variance like strategies: pre-commitment mean variance, time-consistent mean variance, and mean quadratic variation, assuming realistic investment constraints (e.g. no bankruptcy, finite shorting, borrowing). When the investment policy is constrained, the efficient frontiers for all three objective functions are similar, but the optimal policies are quite different.

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