Assessing environmental risks through fuzzy parameterized probabilistic analysis

Qin, Xiaosheng

doi:10.1007/s00477-010-0454-4

Cited by 41 publications

(7 citation statements)

References 48 publications

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“…Owing to the development of copula methods, amounts of research efforts have been proposed for multivariate hydrologic risk analysis (Zhang and Singh 2006;Xu et al 2010;Fan et al 2012Fan et al , 2015aZhang et al 2013, Cantet andArnaud 2014;Sraj et al 2014;Kong et al 2015;Ming et al 2015;Saad et al 2015). The main advantage of copula functions over classical multivariate hydrologic modelling is that the marginal distributions and multivariate dependence modelling can be determined in two separate processes, giving additional flexibility to the practitioner in choosing different marginal and joint probability functions (Zhang and Singh 2006;Genest and Favre 2007;Qin 2012;Sraj et al 2014;Fan et al 2015b). …”

Section: Introductionmentioning

confidence: 98%

Multivariate flood risk analysis for Wei River

Huang

Fan

2015

Stoch Environ Res Risk Assess

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In this study, bivariate hydrologic risk analysis was conducted based on the daily streamflow discharge at the Xianyang station on the Wei River. This bivariate hydrologic risk analysis was conducted based on copula methods, in which the bivariate hydrologic frequency was firstly quantified through copulas, and the bivariate hydrologic risk analysis was then characterized based on the joint return period of flood pairs. The maximum likelihood estimation (MLE) and the method-of-moments-like (MOM) estimator were compared in estimating the unknown parameters in copula. The results showed that the GumbelHougaard copula was most appropriate for modelling the dependence for all three flood pairs, in which the parameter of the copula for flood peak-volume was estimated by MLE and the parameters of the copulas for flood peak-duration and volume-duration were needed to be obtained by MOM. The bivariate hydrologic risk values are then obtained based on the AND-joint return period. The results show that the bivariate hydrologic values will not decrease until the corresponding volume for a flood is larger than 1.0 9 10 4 m 3 /s. For the bivariate hydrologic risk for flood peak-duration, the value will decrease quickly when the duration is longer than 5 days. Such bivariate hydrologic risk analysis can provide decision support for hydraulic facility design as well as actual flood control and mitigation.

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Section: Introductionmentioning

confidence: 98%

Multivariate flood risk analysis for Wei River

Huang

Fan

2015

Stoch Environ Res Risk Assess

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“…For example, Qin (2012) developed a fuzzy parameterized probabilistic analysis (FPPA) method to assess risks associated with environmental pollution-control problems. The results indicated that complex uncertain features had significant impacts on modeling and risk-assessment outputs [25]. Li et al (2015) presented an integrated optimal groundwater remediation design approach that incorporated numerical simulation, health-risk assessment, uncertainty analysis, and non-linear optimization within a general framework [3].…”

Section: Introductionmentioning

confidence: 99%

An Integrated Simulation, Inference and Optimization Approach for Groundwater Remediation with Two-Stage Health-Risk Assessment

Yang

Yang²,

Fan

et al. 2018

Water

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In this study, an integrated simulation, inference and optimization approach with two-stage health risk assessment (i.e., ISIO-THRA) is developed for supporting groundwater remediation for a petroleum-contaminated site in western Canada. Both environmental standards and health risk are considered as the constraints in the ISIO-THRA model. The health risk includes two parts: (1) the health risk during the remediation process and (2) the health risk in the natural attenuation period after remediation. In the ISIO-THRA framework, the relationship between contaminant concentrations and time is expressed through first-order decay models. The results demonstrate that: (1) stricter environmental standards and health risk would require larger pumping rates for the same remediation duration; (2) higher health risk may happen in the period of the remediation process; (3) for the same environmental standard and acceptable health-risk level, the remediation techniques that take the shortest time would be chosen. ISIO-THRA can help to systematically analyze interaction among contaminant transport, remediation duration, and environmental and health concerns, and further provide useful supportive information for decision makers.

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“…To reflect such uncertainties in EPS, inexact system-analysis techniques can be used (Gong et al, 2016;Lin et al, 2016;Tong et al, 2016). Examples are interval parameter programming (IPP) (Huang et al, 1992(Huang et al, , 2011Grosfeld-Nir and Tishler, 1993;Lin and Huang, 2008;Li et al, , 2013, stochastic mathematical programming (SMP) (Grosfeld-Nir et al, 1993;Darby-Dowman et al, 2000;Xie et al, 2010;Pousinho et al, 2011;Svensson et al, 2011;Qin, 2012;Wang et al, 2012) and fuzzy linear programming (FLP) (Huang et al, 1993;Huang et al, 1996;Yin et al, 1999;Chanas and Zielinski, 2000;Li et al, 2007;Muela et al, 2007;Lu et al, 2008).…”

Section: Introductionmentioning

confidence: 99%

An Inexact Credibility Chance-Constrained Integer Programming for Greenhouse Gas Mitigation Management in Regional Electric Power System under Uncertainty

Li¹

2016

J ENV INFORM

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Electric power system (EPS) management considering greenhouse gas (GHG) mitigation is a challenging task, since many system parameters such as electric demand, resource availability, system cost as well as their interrelationships may appear uncertain. To reflect these uncertainties, in this study, an interval-parameter credibility constrained programming (ICCP) method was developed for electric power system planning in light of GHG mitigation. The method was advantageous in tackling uncertainties expressed as not only fuzzy possibilistic distributions associated with the right-hand-side components of model constraints but also discrete intervals in the objective function. In addition, ICCP allowed satisfaction of system constraints at specified confidence level, leading to model solutions with low system cost under acceptable risk magnitudes. The obtained results indicated that stable intervals for the objective function and decision variables could be generated, which were useful for helping decision makers identify the desired electric power generation patterns, capacity expansion schemes and GHG-emission reduction under complex uncertainties, and gain in-depth insights into the trade-offs between system economy and reliability.

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Assessing environmental risks through fuzzy parameterized probabilistic analysis

Cited by 41 publications

References 48 publications

Multivariate flood risk analysis for Wei River

Multivariate flood risk analysis for Wei River

An Integrated Simulation, Inference and Optimization Approach for Groundwater Remediation with Two-Stage Health-Risk Assessment

An Inexact Credibility Chance-Constrained Integer Programming for Greenhouse Gas Mitigation Management in Regional Electric Power System under Uncertainty

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