Abstract
Abstract. Process-based models are powerful tools for simulating the economic impacts of climate change, but they are computationally expensive. In order to project climate-change impacts under various scenarios, produce probabilistic ensembles, conduct online coupled simulations, or explore pathways by numerical optimization, the computational and implementation cost of economic impact calculations should be reduced. To do so, in this study, we developed various emulators that mimic the behaviours of simulation models, namely economic models coupled with bio/physical-process-based impact models, by statistical regression techniques. Their performance was evaluated for multiple sectors and regions. Among the tested emulators, those composed of artificial neural networks, which can incorporate non-linearities and interactions between variables, performed better particularly when finer input variables were available. Although simple functional forms were effective for approximating general tendencies, complex emulators are necessary if the focus is regional or sectoral heterogeneity. Since the computational cost of the developed emulators is sufficiently small, they could be used to explore future scenarios related to climate-change policies. The findings of this study could also help researchers design their own emulators in different situations.
Highlights
Climate change has diverse impacts on society and a wide range of sectors (IPCC, 2014), and these impacts should be quantitatively evaluated to manage overall risks
We report results for r in the main text since the three metrics (r, root mean squared error (RMSE), and RMSE to standard deviation (RSR)) varied almost parallelly, and systematic errors were nearly negligible for all conditions
Summarized results beyond r (RMSE, RSR, and bias) are available in Tables S4 to S13 in the Supplement, and individual values for all sectors and regions are available as electronic supplementary material
Summary
Climate change has diverse impacts on society and a wide range of sectors (IPCC, 2014), and these impacts should be quantitatively evaluated to manage overall risks. If we can monetize these impacts, a variety of risks across different sectors and regions can be considered on a unified scale This information helps us to design climate-change-related policies. Process-based bio/physical impact models coupled with an economic model are widely used, and they tend to be elaborate and complex (Weyant, 2017; Diaz and Moore, 2017). Process-based simulations can contribute to deeper understanding of the focal phenomena, and they can simulate outcomes under purely counterfactual conditions that never occurred in the past.
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