Approximating zero-variance importance sampling in a reliability setting

We consider a class of Markov chain models that includes the highly reliable Markovian systems (HRMS) often used to represent the evolution of multicomponent systems in reliability settings. We are interested in the design of efficient importance sampling (IS) schemes to estimate the reliability of such systems by simulation. For these models, there is in fact a zero-variance IS scheme that can be written exactly in terms of a value function that gives the expected cost-to-go (the exact reliability, in our case) from any state of the chain. This IS scheme is impractical to implement exactly, but it can be approximated by approximating this value function. We examine how this can be effectively used to estimate the reliability of a highly-reliable multicomponent system with Markovian behavior. In our implementation, we start with a simple crude approximation of the value function, we use it in a first-order IS scheme to obtain a better approximation at a few selected states, then we interpolate in between and use this interpolation in our final (second-order) IS scheme. In numerical illustrations, our approach outperforms the popular IS heuristics previously proposed for this class of problems. We also perform an asymptotic analysis in which the HRMS model is parameterized in a standard way by a rarity parameter ε, so that the relative error (or relative variance) of the crude Monte Carlo estimator is unbounded when ε→0. We show that with our approximation, the IS estimator has bounded relative error (BRE) under very mild conditions, and vanishing relative error (VRE), which means that the relative error converges to 0 when ε→0, under slightly stronger conditions.

[1]  Marvin K. Nakayama,et al.  QUICK SIMULATION METHODS FOR ESTIMATING THE UNRELIABILITY OF REGENERATIVE MODELS OF LARGE, HIGHLY RELIABLE SYSTEMS , 2004, Probability in the Engineering and Informational Sciences.

[2]  Donald L. Iglehart,et al.  Importance sampling for stochastic simulations , 1989 .

[3]  Charles Leake,et al.  Discrete Event Systems: Sensitivity Analysis and Stochastic Optimization by the Score Function Method , 1994 .

[4]  Marvin K. Nakayama,et al.  Techniques for fast simulation of models of highly dependable systems , 2001, IEEE Trans. Reliab..

[5]  Pierre L'Ecuyer,et al.  Simulation in Java with SSJ , 2005, Proceedings of the Winter Simulation Conference, 2005..

[6]  Marvin K. Nakayama,et al.  General conditions for bounded relative error in simulations of highly reliable Markovian systems , 1996, Advances in Applied Probability.

[7]  Bruno Tuffin,et al.  On numerical problems in simulations of highly reliable Markovian systems , 2004, First International Conference on the Quantitative Evaluation of Systems, 2004. QEST 2004. Proceedings..

[8]  Peter W. Glynn,et al.  Stochastic Simulation: Algorithms and Analysis , 2007 .

[9]  Bruno Tuffin,et al.  Approximate zero-variance simulation , 2008, 2008 Winter Simulation Conference.

[10]  Jerome Spanier A New Multistage Procedure for Systematic Variance Reduction in Monte Carlo , 1971 .

[11]  S. Juneja,et al.  Rare-event Simulation Techniques : An Introduction and Recent Advances , 2006 .

[12]  Perwez Shahabuddin,et al.  Fast Transient Simulation of Markovian Models of Highly Dependable Systems , 1994, Perform. Evaluation.

[13]  Peter W. Glynn,et al.  Asymptotic robustness of estimators in rare-event simulation , 2007, TOMC.

[14]  Juan A. Carrasco Failure distance-based simulation of repairable fault-tolerant systems , 1992 .

[15]  Dennis D. Cox,et al.  Adaptive importance sampling on discrete Markov chains , 1999 .

[16]  Pierre L'Ecuyer,et al.  EFFECTIVE APPROXIMATION OF ZERO-VARIANCE SIMULATION IN A RELIABILITY SETTING , 2007 .

[17]  Perwez Shahabuddin,et al.  Importance sampling for the simulation of highly reliable Markovian systems , 1994 .

[18]  P. Shahabuddin,et al.  Chapter 11 Rare-Event Simulation Techniques: An Introduction and Recent Advances , 2006, Simulation.

[19]  Vivek S. Borkar,et al.  Adaptive Importance Sampling Technique for Markov Chains Using Stochastic Approximation , 2006, Oper. Res..

[20]  Gerardo Rubino,et al.  MTTF Estimation using importance sampling on Markov models , 2002, Monte Carlo Methods Appl..

[21]  Philip Heidelberger,et al.  Varaince reduction in mean time to failure simulations (1988) , 2007, WSC '07.

[22]  Bruno Tuffin On numerical problems in simulations of highly reliable Markovian systems , 2004 .

[23]  Philip Heidelberger,et al.  A Unified Framework for Simulating Markovian Models of Highly Dependable Systems , 1992, IEEE Trans. Computers.

[24]  T. E. Booth,et al.  Exponential convergence for Monte Carlo particle transport , 1985 .

[25]  P. Glynn,et al.  Varaince reduction in mean time to failure simulations , 1988, 1988 Winter Simulation Conference Proceedings.

[26]  Sandeep Juneja,et al.  Splitting-based importance-sampling algorithm for fast simulation of Markov reliability models with general repair-policies , 2001, IEEE Trans. Reliab..

[27]  HeidelbergerPhilip Fast simulation of rare events in queueing and reliability models , 1995 .

[28]  Philip Heidelberger,et al.  Fast simulation of rare events in queueing and reliability models , 1993, TOMC.

[29]  Jason H. Goodfriend,et al.  Discrete Event Systems: Sensitivity Analysis and Stochastic Optimization by the Score Function Method , 1995 .

[30]  Sandeep Juneja,et al.  Fast Simulation of Markov Chains with Small Transition Probabilities , 2001, Manag. Sci..

[31]  I. Gertsbakh Asymptotic methods in reliability theory: a review , 1984, Advances in Applied Probability.

[32]  Christos Alexopoulos,et al.  Estimating reliability measures for highly-dependable Markov systems, using balanced likelihood ratios , 2001, IEEE Trans. Reliab..

[33]  Thomas E. Booth,et al.  Generalized zero-variance solutions and intelligent random numbers , 1987, WSC '87.

[34]  Bruno Tuffin,et al.  Splitting with weight windows to control the likelihood ratio in importance sampling , 2006, valuetools '06.