Abstract
Energy system optimization models used for capacity expansion and dispatch planning are established tools for decision-making support in both energy industry and energy politics. The ever-increasing complexity of the systems under consideration leads to an increase in mathematical problem size of the models. This implies limitations of today’s common solution approaches especially with regard to required computing times. To tackle this challenge many model-based speed-up approaches exist which, however, are typically only demonstrated on small generic test cases. In addition, in applied energy systems analysis the effects of such approaches are often not well understood. The novelty of this study is the systematic evaluation of several model reduction and heuristic decomposition techniques for a large applied energy system model using real data and particularly focusing on reachable speed-up. The applied model is typically used for examining German energy scenarios and allows expansion of storage and electricity transmission capacities. We find that initial computing times of more than two days can be reduced up to a factor of ten while having acceptable loss of accuracy. Moreover, we explain what we mean by “effectiveness of model reduction” which limits the possible speed-up with shared memory computers used in this study.
Highlights
Concerning an efficient execution of GAMS, in addition to the suggestions mentioned in Section 3.1., we observed that it is always advisable to use a consistent order of sets
We investigated the hypothesis that ordering the index sets from the largest cardinality to the smallest would reduce the time for the model generation
Energy systems analysis highly depends on modeling tools such as Energy System Optimization models (ESOMs)
Summary
Given the envisaged creation of a common European energy market and the transformation of energy supply towards sectoral coupling and electricity generation from variable renewable energy sources (vRES), this trend can be expected to continue. In this context, new energy policies are often investigated with the help of linear optimization models [1]. Existing and especially future research questions in the field of energy system analysis can only be addressed to a limited extent. In applied studies, this challenge is tackled with different strategies. The majority of currently applied speed-up strategies still
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