A generalized many‐objective optimization approach for scenario discovery

Kwakkel, Jan H.

doi:10.1002/ffo2.8

Cited by 26 publications

(24 citation statements)

References 63 publications

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“…Scenario discovery is most typically performed using the Patient Rule Induction Method (PRIM) (Friedman & Fisher, 1999) or Classification and Regression Trees (CART) (Breiman, 1984). One of the main criticisms of these methods is that they rely on orthogonal subspaces to classify the parameter space into success or failure, making their application to nonlinear systems inadequate (Kwakkel, 2019). Logistic regression is a common technique in binary classification problems that overcomes this limitation by using a nonlinear function to describe the probability that a SOW belongs to the scenarios that lead to failure (Lamontagne et al, 2019; Trindade et al, 2019).…”

Section: Methodological Frameworkmentioning

confidence: 99%

Defining Robustness, Vulnerabilities, and Consequential Scenarios for Diverse Stakeholder Interests in Institutionally Complex River Basins

et al. 2020

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The Upper Basin of the Colorado River in the southwestern United States supports municipal, industrial, agricultural, and recreational activities worth an estimated $300 billion/year within the state of Colorado alone. The allocation of water to these activities is fundamentally shaped by water rights that in turn distribute risks among a diverse suite of sectors and stakeholders. In this study, we assess the vulnerabilities faced by the hierarchy of hundreds of water users in the portion of the Upper Basin within the state of Colorado, as a result of changes in hydrologic extremes, demand growth, and institutional and physical infrastructure in the basin. We also determine how robust the different users are to these potential changes, examining how their sensitivity to these factors depends on the magnitude and frequency of shortage they are unwilling to exceed. This advances previous robustness evaluation methods by formalizing an a posteriori exploration of alternative definitions of robustness tailored to each user's unique context. Our analysis reveals that robustness varies significantly not only across users but also across different definitions of acceptable performance for each user. We further show the importance of using scenario discovery to evaluate how the factors that drive consequential scenarios differ depending on the definition of robustness. Our results highlight the need for robustness and vulnerability frameworks to avoid broad categorical aggregations of stakeholder groups, to carefully capture complex institutional dependencies (e.g., water rights), and to facilitate a more transparent illustration of the implications of alternative definitions of robustness for specific stakeholders.

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Section: Methodological Frameworkmentioning

confidence: 99%

Defining Robustness, Vulnerabilities, and Consequential Scenarios for Diverse Stakeholder Interests in Institutionally Complex River Basins

et al. 2020

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“…Scenario discovery is a computer‐assisted approach to scenario development that identifies regions of the uncertainty space that are tied to outcomes of interest (Bryant & Lempert, 2010; Kwakkel, 2019). These methods begin by sampling possible values of uncertain factors, which are then simulated using one or more system models to generate a large ensemble of potential future system conditions.…”

Section: Scenario Discovery and Characterizing Dynamicsmentioning

confidence: 99%

Uncertainty Analysis in Multi‐Sector Systems: Considerations for Risk Analysis, Projection, and Planning for Complex Systems

et al. 2022

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Simulation models of multi‐sector systems are increasingly used to understand societal resilience to climate and economic shocks and change. However, multi‐sector systems are also subject to numerous uncertainties that prevent the direct application of simulation models for prediction and planning, particularly when extrapolating past behavior to a nonstationary future. Recent studies have developed a combination of methods to characterize, attribute, and quantify these uncertainties for both single‐ and multi‐sector systems. Here, we review challenges and complications to the idealized goal of fully quantifying all uncertainties in a multi‐sector model and their interactions with policy design as they emerge at different stages of analysis: (a) inference and model calibration; (b) projecting future outcomes; and (c) scenario discovery and identification of risk regimes. We also identify potential methods and research opportunities to help navigate the tradeoffs inherent in uncertainty analyses for complex systems. During this discussion, we provide a classification of uncertainty types and discuss model coupling frameworks to support interdisciplinary collaboration on multi‐sector dynamics (MSD) research. Finally, we conclude with recommendations for best practices to ensure that MSD research can be properly contextualized with respect to the underlying uncertainties.

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“…Beyond the discovery of robust planning alternatives, exploratory modeling approaches also enable decision makers to discover consequential future scenarios that cause vulnerabilities in candidate alternatives (Lempert et al, 2006). Typically, the process of scenario discovery utilizes data mining, machine learning, and/or multi-objective optimization to delineate critical thresholds in the uncertainty space that cause proposed alternatives to fail to meet performance criteria defined by stakeholders (Bryant & Lempert, 2010;Groves & Lempert, 2007;Kwakkel, 2019). In the MORDM framework, scenario discovery is a core component of an iterative problem formulation process, which allows stakeholders to learn from exploratory modeling results to improve their understanding of their preferences and potential actions (Kasprzyk et al, 10.1029/2019WR025462 2013; .…”

Section: Research Articlementioning

confidence: 99%

Identifying Actionable Compromises: Navigating Multi‐City Robustness Conflicts to Discover Cooperative Safe Operating Spaces for Regional Water Supply Portfolios

Gold

Reed

Trindade

et al. 2019

Water Resources Research

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Regional cooperation among water utilities can improve the robustness of urban water supply systems to challenging and deeply uncertain futures. Through coordination mechanisms such as water transfers and regional demand management, water utilities can improve the efficiency of resource allocation and delay the need for new infrastructure investments. Though cooperation provides utilities with the potential for reduced cost strategies for improving the reliability of their services, two important challenges are worthy of careful consideration. First, regional utilities often have to navigate robustness conflicts stemming from potential asymmetries in their risk exposure, demand dynamics, and the availability of supply resources. Second, successful implementation of candidate compromise water portfolios requires that cooperating utilities understand their operational tolerances to deviations from the recommended regional actions (“imperfect implementation”). This study contributes a framework for identifying compromises across regional robustness conflicts and quantifying tolerances to implementation uncertainties. The framework is demonstrated on a system of four interdependent but institutionally independent water utilities in the Research Triangle region of North Carolina that are confronting robustness conflicts given asymmetries in their vulnerabilities to growing demands and hydroclimatic uncertainties. Our findings highlight that seemingly balanced compromise management strategies can yield significant and potentially surprising unintended consequences that could degrade regional cooperation. Moreover, asymmetries in regional robustness can be amplified with modest deviations from their agreed upon actions. Results of this analysis are broadly applicable to water supply regionalization as a global challenge and provide insights for discovering robust compromises and safe operating spaces for multi‐actor water supply systems.

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A generalized many‐objective optimization approach for scenario discovery

Cited by 26 publications

References 63 publications

Defining Robustness, Vulnerabilities, and Consequential Scenarios for Diverse Stakeholder Interests in Institutionally Complex River Basins

Defining Robustness, Vulnerabilities, and Consequential Scenarios for Diverse Stakeholder Interests in Institutionally Complex River Basins

Uncertainty Analysis in Multi‐Sector Systems: Considerations for Risk Analysis, Projection, and Planning for Complex Systems

Identifying Actionable Compromises: Navigating Multi‐City Robustness Conflicts to Discover Cooperative Safe Operating Spaces for Regional Water Supply Portfolios

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