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Proximal algorithms and temporal difference methods for solving fixed point problems

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  • Dimitri P. Bertsekas

    (M.I.T.)

Abstract

In this paper we consider large fixed point problems and solution with proximal algorithms. We show that for linear problems there is a close connection between proximal iterations, which are prominent in numerical analysis and optimization, and multistep methods of the temporal difference type such as TD( $$\lambda $$ λ ), LSTD( $$\lambda $$ λ ), and LSPE( $$\lambda $$ λ ), which are central in simulation-based exact and approximate dynamic programming. One benefit of this connection is a new and simple way to accelerate the standard proximal algorithm by extrapolation towards a multistep iteration, which generically has a faster convergence rate. Another benefit is the potential for integration into the proximal algorithmic context of several new ideas that have emerged in the approximate dynamic programming context, including simulation-based implementations. Conversely, the analytical and algorithmic insights from proximal algorithms can be brought to bear on the analysis and the enhancement of temporal difference methods. We also generalize our linear case result to nonlinear problems that involve a contractive mapping, thus providing guaranteed and potentially substantial acceleration of the proximal and forward backward splitting algorithms at no extra cost. Moreover, under certain monotonicity assumptions, we extend the connection with temporal difference methods to nonlinear problems through a linearization approach.

Suggested Citation

  • Dimitri P. Bertsekas, 2018. "Proximal algorithms and temporal difference methods for solving fixed point problems," Computational Optimization and Applications, Springer, vol. 70(3), pages 709-736, July.
    • Handle: RePEc:spr:coopap:v:70:y:2018:i:3:d:10.1007_s10589-018-9990-5
    DOI: 10.1007/s10589-018-9990-5
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    References listed on IDEAS

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    1. Huizhen Yu & Dimitri Bertsekas, 2013. "Q-learning and policy iteration algorithms for stochastic shortest path problems," Annals of Operations Research, Springer, vol. 208(1), pages 95-132, September.
    2. Dimitri P. Bertsekas & Huizhen Yu, 2012. "Q-Learning and Enhanced Policy Iteration in Discounted Dynamic Programming," Mathematics of Operations Research, INFORMS, vol. 37(1), pages 66-94, February.
    3. Hu, Qinghua & Zhang, Rujia & Zhou, Yucan, 2016. "Transfer learning for short-term wind speed prediction with deep neural networks," Renewable Energy, Elsevier, vol. 85(C), pages 83-95.
    4. David Silver & Aja Huang & Chris J. Maddison & Arthur Guez & Laurent Sifre & George van den Driessche & Julian Schrittwieser & Ioannis Antonoglou & Veda Panneershelvam & Marc Lanctot & Sander Dieleman, 2016. "Mastering the game of Go with deep neural networks and tree search," Nature, Nature, vol. 529(7587), pages 484-489, January.
    5. Huizhen Yu & Dimitri P. Bertsekas, 2010. "Error Bounds for Approximations from Projected Linear Equations," Mathematics of Operations Research, INFORMS, vol. 35(2), pages 306-329, May.
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