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North American Actuarial Journal Volume 23, 2019 - Issue 3
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Feature Articles

Management of Portfolio Depletion Risk through Optimal Life Cycle Asset Allocation

Peter A. ForsythCheriton School of Computer Science, University of Waterloo, Waterloo, Ontario, CanadaCorrespondence[email protected]
ORCID Iconhttp://orcid.org/0000-0001-7841-7891View further author information
ORCID Icon,
Kenneth R. VetzalSchool of Accounting and Finance, University of Waterloo, Waterloo, Ontario, CanadaView further author information
&
Graham WestmacottPWL Capital, Waterloo, Ontario, CanadaView further author information
Pages 447-468 | Published online: 14 Jun 2019

References

  • Arnott, R. D., K. F. Sherrerd, and L. Wu. 2013. The glidepath illusion and potential solutions. Journal of Retirement 1 (2): 13–28.
  • Basak, S., and G. Chabakauri. 2010. Dynamic mean-variance asset allocation. Review of Financial Studies 23: 2970–3016.
  • Björk, T., A. Murgoci, and X. Y. Zhou. 2014. Mean variance portfolio optimization with state dependent risk aversion. Mathematical Finance 24: 1–24.
  • Blake, D., A. J. G. Cairns, and K. Dowd. 2003. Pensionmetrics 2: Stochastic pension plan design during the distribution phase. Insurance: Mathematics and Economics 33: 29–47.
  • Blake, D., D. Wright, and Y. Zhang. 2014. Age-dependent investing: Optimal funding and investment strategies in defined contribution pension plans when members are rational life cycle financial planners. Journal of Economic Dynamics and Control 38: 105–124.
  • Cairns, A. J. G., D. Blake, and K. Dowd. 2006. Stochastic lifestyling: Optimal dynamic asset allocation for defined contribution pension plans. Journal of Economic Dynamics and Control 30: 843–977.
  • Campanele, C., C. Fugazza, and F. Gomes. 2015. Life-cycle portfolio choice with liquid and illiquid financial assets. Journal of Monetary Economics 71: 67–83.
  • Chen, A., and L. Delong. 2015. Optimal investment for a defined-contribution pension scheme under a regime switching model. ASTIN Bulletin 45: 397–419.
  • Christiansen, M. C., and M. Steffensen. 2018. Around the life cycle: Deterministic consumption-investment strategies. North American Actuarial Journal, forthcoming.
  • Cocco, J. F., F. J. Gomes, and P. J. Maenhout. 2005. Consumption and portfolio choice over the life cycle. Review of Financial Studies 18: 491–533.
  • Cogneau, P., and V. Zakalmouline. 2013. Block bootstrap methods and the choice of stocks for the long run. Quantitative Finance 13: 1443–1457.
  • Cong, F., and C. W. Oosterlee. 2016. Multi-period mean variance portfolio optimization based on Monte-Carlo simulation. Journal of Economic Dynamics and Control 64: 23–38.
  • Cont, R., and C. Mancini. 2011. Nonparametric tests for pathwise properties of semimartingales. Bernoulli 17: 781–813.
  • Dahlquist, M., O. Setty, and R. Vestman. 2018. On the asset allocation of a default pension fund. Journal of Finance 73: 1893–1936.
  • Dammon, R. M., C. S. Spatt, and H. H. Zhang. 2004. Optimal asset location and allocation with taxable and tax-deferred investing. Journal of Finance 59: 999–1037.
  • Dang, D.-M., and P. A. Forsyth. 2014. Continuous time mean-variance optimal portfolio allocation under jump diffusion: A numerical impulse control approach. Numerical Methods for Partial Differential Equations 30: 664–698.
  • Dang, D.-M., and P. A. Forsyth. 2016. Better than pre-commitment mean-variance portfolio allocation strategies: A semi-self-financing Hamilton-Jacobi-Bellman equation approach. European Journal of Operational Research 250: 827–841.
  • Dang, D.-M., P. A. Forsyth, and K. R. Vetzal. 2017. The 4% strategy revisited: A pre-commitment optimal mean-variance approach to wealth management. Quantitative Finance 17: 335–351.
  • Dichtl, H., W. Drobetz, and M. Wambach. 2016. Testing rebalancing strategies for stock-bond portfolos across different asset allocations. Applied Economics 48: 772–788.
  • Donnelly, C., R. Gerrard, M. Guillén, and J. P. Nielsen, 2015. Less is more: Increasing retirement gains by using an upside terminal wealth constraint. Insurance: Mathematics and Economics 64: 259–267.
  • Donnelly, C., M. Guillén, J. P. Nielsen, and A. M. Pérez-Marín. 2017. Implementing individual savings decisions for retirement with bounds on wealth. ASTIN Bulletin 48: 111–137.
  • Fagereng, A., C. Gottlieb, and L. Guiso. 2017. Asset market participation and portfolio choice over the life-cycle. Journal of Finance 72: 705–750.
  • Forsyth, P., and G. Labahn. 2019. ϵ-monotone Fourier methods for optimal stochastic control in finance. Journal of Computational Finance, 22: 25–71.
  • Forsyth, P. A., and K. R. Vetzal. 2017a. Dynamic mean variance asset allocation: Tests for robustness. International Journal of Financial Engineering 4 (2): 1750021. https://doi.org/10.1142/S2424786317500219.
  • Forsyth, P. A., and K. R. Vetzal. 2017b. Robust asset allocation for long-term target-based investing. International Journal of Theoretical and Applied Finance 20 (3): 1750017. https://doi.org/10.1142/S0219024917500170.
  • Forsyth, P. A., and K. R. Vetzal. 2018. Optimal asset allocation for retirement savings: Deterministic vs. time conistent adaptive strategies. Working paper, University of Waterloo.
  • Forsyth, P. A., K. R. Vetzal, and G. Westmacott. 2017. Target wealth: The evolution of target date funds. White paper, PWL Capital. www.pwlcapital.com/en/The-Firm/White-Papers.
  • Freedman, B. 2008. Efficient post-retirement asset allocation. North American Actuarial Journal 12: 228–241.
  • Gao, J., K. Zhou, D. Li, and X. Cao. 2017. Dynamic mean-LPM and mean-CVaR portfolio optimization in continuous-time. SIAM Journal on Control and Optimization 55: 1377–1397.
  • Gerrard, R., S. Haberman, and E. Vigna. 2004. Optimal investment choices post-retirement in a defined contribution pension scheme. Insurance: Mathematics and Economics 35: 321–342.
  • Gerrard, R., S. Haberman, and E. Vigna. 2006. The management of decumulation risk in a defined contribution pension plan. North American Actuarial Journal 10: 84–110.
  • Graf, S. 2017. Life-cycle funds: Much ado about nothing? European Journal of Finance 23: 974–998.
  • Guan, G., and Z. Liang. 2014. Optimal management of DC pension plan in a stochastic interest rate and stochastic volatility framework. Insurance: Mathematics and Economics 57: 58–66.
  • Horneff, V., R. Maurer, O. S. Mitchell, and R. Rogalla. 2015. Optimal life cycle portfolio choice with variable annuities offering liquidity and investment downside protection. Insurance: Mathematics and Economics 63: 91–107.
  • Kou, S. G., and H. Wang. 2004. Option pricing under a double exponential jump diffusion model. Management Science 50: 1178–1192.
  • Li, D., and W.-L. Ng. 2000. Optimal dynamic portfolio selection: Multiperiod mean-variance formulation. Mathematical Finance 10: 387–406.
  • Liang, X., and V. R. Young. 2018. Annuitization and asset allocation under exponential utility. Insurance: Mathematics and Economics 79: 167–183.
  • Ma, K., and P. A. Forsyth. 2016. Numerical solution of the Hamilton-Jacobi-Bellman formulation for continuous time mean variance asset allocation under stochastic volatility. Journal of Computational Finance 20 (1): 1–37.
  • MacDonald, B.-J., B. Jones, R. J. Morrison, R. L. Brown, and M. Hardy. 2013. Research and reality: A literature review on drawing down retirement financial savings. North American Actuarial Journal 17: 181–215.
  • Mancini, C. 2009. Non-parametric threshold estimation models with stochastic diffusion coefficient and jumps. Scandinavian Journal of Statistics 36: 270–296.
  • Menoncin, F., and E. Vigna. 2017. Mean-variance target based optimisation for defined contribution pension schemes in a stochastic framework. Insurance: Mathematics and Economics 76: 172–184.
  • Michaelides, A., and Y. Zhang. 2017. Stock market mean reversion and portfolio choice over the life cycle. Journal of Financial and Quantitative Analysis 52: 1183–1209.
  • Milevsky, M. A., and V. R. Young. 2007. Annuitization and asset allocation. Journal of Economic Dynamics and Control 31: 3138–3177.
  • Miller, C., and I. Yang. 2017. Optimal control of conditional value-at-risk in continuous time. SIAM Journal on Control and Optimization 55: 856–884.
  • O’Hara, M., and T. Daverman. 2017. Reexamining “to versus through.” White Paper, BlackRock. www.blackrock.com/investing/literature/whitepaper/to-versus-through-whitepaper.pdf.
  • Patton, A., D. Politis, and H. White. 2009. Correction to: Automatic block-length selection for the dependent bootstrap. Econometric Reviews 28: 372–375.
  • Peijnenburg, K., T. Nijman, and B. J. M. Werker. 2016. The annuity puzzle remains a puzzle. Journal of Economic Dynamics and Control 70: 18–35.
  • Politis, D., and H. White. 2004. Automatic block-length selection for the dependent bootstrap. Econometric Reviews 23: 53–70.
  • Ritholz, B. 2017. Tackling the ‘nastiest, hardest problem in finance.’ www.bloomberg.com/view/articles/2017-06-05/tackling-the-nastiest-hardest-problem-in-finance.
  • Rockafellar, R. T., and S. Uryasev. 2000. Optimization of conditional value-at-risk. Journal of Risk 2: 21–42.
  • Rupert, P., and G. Zanella. 2015. Revisiting wage, earnings, and hours profiles. Journal of Monetary Economics 72: 114–130.
  • Smith, G., and D. P. Gould. 2007. Measuring and controlling shortfall risk in retirement. Journal of Investing 16: 82–95.
  • Strub, M., D. Li, X. Cui, and J. Gao. 2017. Discrete-time Mean-CVaR portfolio selection and time-consistency induced term structure of the CVaR. SSRN abstract 3040517.
  • Tretiakova, I., and M. S. Yamada. 2011. What DC plan members really want. Rotman International Journal of Pension Management 4: 60–70.
  • Vigna, E. 2014. On efficiency of mean-variance based portfolio selection in defined contribution pension schemes. Quantitative Finance 14: 237–258.
  • Vigna, E. 2017. Tail optimality and preferences consistency for intertemporal optimization problems. Working paper, Collegio Carlo Alberto, Università Degli Studi di Torino.
  • Waring, M., and L. Siegel. 2015. The only spending rule you will ever need. Financial Analysts Journal 71: 91–107.
  • Westmacott, G., and S. Daley. 2015. The design and depletion of retirement portfolios. White paper, PWL Capital. www.pwlcapital.com/en/The-Firm/White-Papers.
  • Wu, H., and Y. Zeng. 2015. Equilibrium investment strategy for defined-contribution pension schemes with generalized mean-variance criterion and mortality risk. Insurance: Mathematics and Economics 64: 396–408.
  • Yao, H., Y. Lai, Q. Ma, and M. Jian. 2014. Asset allocation for a DC pension fund with stochastic income and mortality risk: A multi-period mean-variance framework. Insurance: Mathematics and Economics 54: 84–92.
  • Zhang, R., N. Langrené, Y. Tian, Z. Zhu, F. Klebaner, and K. Hamza. 2017. Sharp target range strategy with dynamic portfolio selection: Decensored least squares Monte Carlo. Working paper, Monash University.
  • Zhou, X. Y., and D. Li. 2000. Continuous-time mean-variance portfolio selection: A stochastic LQ framework. Applied Mathematics and Optimization 42: 19–33.

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