Agent-Based Model Calibration Using Machine Learning Surrogates

Lamperti, Francesco; Roventini, Andrea; Sani, Amir

doi:10.2139/ssrn.2943297

Cited by 21 publications

(17 citation statements)

References 102 publications

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“…Calibrating more outputs could be approached by including them as additional objectives, which defines a new scenario where the use of many-objective EMO algorithms will be required. Besides we believe that surrogate fitness functions would be useful for future studies due to the high computational costs of simulating multiple times for every evaluation of a single model configuration [68].…”

Section: Practical Implications and Future Directionsmentioning

confidence: 99%

Evolutionary Multiobjective Optimization for Automatic Agent-Based Model Calibration: A Comparative Study

2021

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Complex problems can be analyzed by using model simulation but its use is not straight-forward since modelers must carefully calibrate and validate their models before using them. This is specially relevant for models considering multiple outputs as its calibration requires handling different criteria jointly. This can be achieved using automated calibration and evolutionary multiobjective optimization methods which are the state of the art in multiobjective optimization as they can find a set of representative Pareto solutions under these restrictions and in a single run. However, selecting the best algorithm for performing automated calibration can be overwhelming. Therefore, we propose to deal with this issue by conducting an exhaustive analysis of the performance of several evolutionary multiobjective optimization algorithms when calibrating several instances of an agent-based model for marketing with multiple outputs. We analyze the calibration results using multiobjective performance indicators and attainment surfaces, including a statistical test for studying the significance of the indicator values, and benchmarking their performance with respect to a classical mathematical method. The results of our experimentation reflect that those algorithms based on decomposition perform significantly better than the remaining methods in most instances. Besides, we also identify how different properties of the problem instances (i.e., the shape of the feasible region, the shape of the Pareto front, and the increased dimensionality) erode the behavior of the algorithms to different degrees.INDEX TERMS Model calibration, agent-based modeling, evolutionary multiobjective optimization.

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Section: Practical Implications and Future Directionsmentioning

confidence: 99%

Evolutionary Multiobjective Optimization for Automatic Agent-Based Model Calibration: A Comparative Study

2021

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“…The main drawback of such a ‘one‐shot’ sampling approach is twofold: (i) there is no well‐established mechanism which enables the analyst to determine the sample size required to generate a metamodel with the desired accuracy level, and (ii) generating a sample with space‐filling property may be redundant for large regions of input space exhibiting homogeneous behaviour in terms of simulation model output. To overcome these weaknesses of ‘one‐shot’ designs, sequential sampling techniques (also known as adaptive sampling and active learning) are extensively used in the literature (Eason & Cremaschi, 2014; Edali & Yücel, 2019; Lamperti, Roventini, & Sani, 2018; Liu, Xu, & Wang, 2015; Xiong, Xiong, Chen, & Yang, 2009). Instead of generating a large ‘one‐shot’ sample for metamodel training, adaptive sequential sampling strategies expand the training set size in an iterative manner by utilizing the knowledge obtained in the earlier sampling and metamodel training iterations.…”

Section: Proposed Approachmentioning

confidence: 99%

“…The function inferred from the simulation input–output data can be considered as an estimated representation of the input–output relationship of the original SDM or IBM and is also called a metamodel, a surrogate model, a proxy, an emulator or a response surface (Kleijnen, 2009; Kleijnen, Sanchez, Lucas, & Cioppa, 2005; Kleijnen & Sargent, 2000). In an attempt towards proposing a systematic and, perhaps, automated model analysis approach for IBMs, several former studies utilize metamodels of different sorts, which guide the process of behaviour space exploration and/or of relationship identification between model inputs and outputs (Chérel, Cottineau, & Reuillon, 2015; Edali & Yücel, 2018; Edali & Yücel, 2019; Edmonds, Little, Lessard‐Phillips, & Fieldhouse, 2014; Lamperti, Roventini, & Sani, 2018).…”

Section: Introductionmentioning

confidence: 99%

Analysis of an individual‐based influenza epidemic model using random forest metamodels and adaptive sequential sampling

Edali

Yücel

2020

Syst Res Behav Sci

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This study proposes a three‐step procedure for the analysis of input–response relationships of dynamic models, which enables the analyst to develop a better understanding about the dynamics of the system. The main building block of the procedure is a random forest metamodel capturing the input–output relationships. We utilize an active learning approach as the second step to improve the accuracy of the metamodel. In the last step, we develop a novel way to present the information captured by the metamodel as a set of intelligible IF–THEN rules. For illustration, we use the FluTE model, which is an individual‐based influenza epidemic model. We observe that the number of daily applicable vaccines determines the success of an intervention strategy the most. Another critical observation is that when the daily available vaccines are constrained, nonpharmaceutical strategies should be incorporated to reduce the extent of the outbreak.

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“…As discussed in , the curse of dimensionality makes the practical application of the tools discussed insofar nearly impossible for medium and large scale ABMs. To address this problem, Lamperti et al (2016b) have proposed to use machine learning surrogates to conveniently filter the parameter space of simulation models, dramatically reducing the computational effort needed to explore the behavior of the model when many parameters are at stake.…”

Section: Model Selection and Empirical Validationmentioning

confidence: 99%

“…Recent developments try to mitigate over-parameterization issues resorting to phase-diagrams (Gualdi et al, 2015), Kriging meta-modeling (Salle and Yıldızoglu, 2014;Dosi et al, 2016c;Bargigli et al, 2016), and machine-learning surrogates (Lamperti et al, 2016b). We shall briefly come back to these issues in the concluding remarks.…”

Section: Model Selection and Empirical Validationmentioning

confidence: 99%

Macroeconomic Policy in DSGE and Agent-Based Models Redux: New Developments and Challenges Ahead

Fagiolo

Roventini

2016

SSRN Journal

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Standard-Nutzungsbedingungen:Die Dokumente auf EconStor dürfen zu eigenen wissenschaftlichen Zwecken und zum Privatgebrauch gespeichert und kopiert werden.Sie dürfen die Dokumente nicht für öffentliche oder kommerzielle Zwecke vervielfältigen, öffentlich ausstellen, öffentlich zugänglich machen, vertreiben oder anderweitig nutzen.Sofern die Verfasser die Dokumente unter Open-Content-Lizenzen (insbesondere CC-Lizenzen) zur Verfügung gestellt haben sollten, gelten abweichend von diesen Nutzungsbedingungen die in der dort genannten Lizenz gewährten Nutzungsrechte. Terms of use: Documents in AbstractThe Great Recession seems to be a natural experiment for economic analysis, in that it has shown the inadequacy of the predominant theoretical framework -the New Neoclassical Synthesis (NNS) -grounded on the DSGE model. In this paper, we present a critical discussion of the theoretical, empirical and political-economy pitfalls of the DSGE-based approach to policy analysis. We suggest that a more fruitful research avenue should escape the strong theoretical requirements of NNS models (e.g., equilibrium, rationality, representative agent, etc.) and consider the economy as a complex evolving system, i.e. as an ecology populated by heterogenous agents, whose far-from-equilibrium interactions continuously change the structure of the system. This is indeed the methodological core of agent-based computational economics (ACE), which is presented in this paper. We also discuss how ACE has been applied to policy analysis issues, and we provide a survey of macroeconomic policy applications (fiscal and monetary policy, bank regulation, labor market structural reforms and climate change interventions). Finally, we conclude by discussing the methodological status of ACE, as well as the problems it raises.

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Agent-Based Model Calibration Using Machine Learning Surrogates

Cited by 21 publications

References 102 publications

Evolutionary Multiobjective Optimization for Automatic Agent-Based Model Calibration: A Comparative Study

Evolutionary Multiobjective Optimization for Automatic Agent-Based Model Calibration: A Comparative Study

Analysis of an individual‐based influenza epidemic model using random forest metamodels and adaptive sequential sampling

Macroeconomic Policy in DSGE and Agent-Based Models Redux: New Developments and Challenges Ahead

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