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Stochastic Response Surface Methods (SRSMs) for Uncertainty Propagation: Application to Environmental and Biological Systems

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  • S. S. Isukapalli
  • A. Roy
  • P. G. Georgopoulos

Abstract

Comprehensive uncertainty analyses of complex models of environmental and biological systems are essential but often not feasible due to the computational resources they require. “Traditional” methods, such as standard Monte Carlo and Latin Hypercube Sampling, for propagating uncertainty and developing probability densities of model outputs, may in fact require performing a prohibitive number of model simulations. An alternative is offered, for a wide range of problems, by the computationally efficient “Stochastic Response Surface Methods (SRSMs)” for uncertainty propagation. These methods extend the classical response surface methodology to systems with stochastic inputs and outputs. This is accomplished by approximating both inputs and outputs of the uncertain system through stochastic series of “well behaved” standard random variables; the series expansions of the outputs contain unknown coefficients which are calculated by a method that uses the results of a limited number of model simulations. Two case studies are presented here involving (a) a physiologically‐based pharmacokinetic (PBPK) model for perchloroethylene (PERC) for humans, and (b) an atmospheric photochemical model, the Reactive Plume Model (RPM‐IV). The results obtained agree closely with those of traditional Monte Carlo and Latin Hypercube Sampling methods, while significantly reducing the required number of model simulations.

Suggested Citation

  • S. S. Isukapalli & A. Roy & P. G. Georgopoulos, 1998. "Stochastic Response Surface Methods (SRSMs) for Uncertainty Propagation: Application to Environmental and Biological Systems," Risk Analysis, John Wiley & Sons, vol. 18(3), pages 351-363, June.
    • Handle: RePEc:wly:riskan:v:18:y:1998:i:3:p:351-363
    DOI: 10.1111/j.1539-6924.1998.tb01301.x
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    Cited by:

    1. Zan Wang & Mitchell J. Small, 2016. "Statistical performance of CO 2 leakage detection using seismic travel time measurements," Greenhouse Gases: Science and Technology, Blackwell Publishing, vol. 6(1), pages 55-69, February.
    2. James D. A. Millington & Hang Xiong & Steve Peterson & Jeremy Woods, 2017. "Integrating Modelling Approaches for Understanding Telecoupling: Global Food Trade and Local Land Use," Land, MDPI, vol. 6(3), pages 1-18, August.
    3. Bohan, A. & Shalloo, L. & Malcolm, B. & Ho, C.K.M. & Creighton, P. & Boland, T.M. & McHugh, N., 2016. "Description and validation of the Teagasc Lamb Production Model," Agricultural Systems, Elsevier, vol. 148(C), pages 124-134.
    4. Oladyshkin, S. & Nowak, W., 2012. "Data-driven uncertainty quantification using the arbitrary polynomial chaos expansion," Reliability Engineering and System Safety, Elsevier, vol. 106(C), pages 179-190.
    5. Oladyshkin, Sergey & Nowak, Wolfgang, 2018. "Incomplete statistical information limits the utility of high-order polynomial chaos expansions," Reliability Engineering and System Safety, Elsevier, vol. 169(C), pages 137-148.
    6. Rituparna Chutia, 2013. "Environmental risk modelling under probability-normal interval-valued fuzzy number," Fuzzy Information and Engineering, Springer, vol. 5(3), pages 359-371, September.
    7. Shalimova Irina A. & Sabelfeld Karl K., 2017. "Stochastic polynomial chaos expansion method for random Darcy equation," Monte Carlo Methods and Applications, De Gruyter, vol. 23(2), pages 101-110, June.
    8. Panos G. Georgopoulos & Christopher J. Brinkerhoff & Sastry Isukapalli & Michael Dellarco & Philip J. Landrigan & Paul J. Lioy, 2014. "A Tiered Framework for Risk‐Relevant Characterization and Ranking of Chemical Exposures: Applications to the National Children's Study (NCS)," Risk Analysis, John Wiley & Sons, vol. 34(7), pages 1299-1316, July.
    9. J. Yang & B. Faverjon & D. Dureisseix & P. Swider & S. Marburg & H. Peters & N. Kessissoglou, 2016. "Prediction of the intramembranous tissue formation during perisprosthetic healing with uncertainties. Part 2. Global clinical healing due to combination of random sources," Computer Methods in Biomechanics and Biomedical Engineering, Taylor & Francis Journals, vol. 19(13), pages 1387-1394, October.

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