TY - JOUR
T1 - A stochastic multiscale model for electricity generation capacity expansion
AU - Parpas, Panos
AU - Webster, Mort
N1 - Funding Information:
The authors wish to acknowledge the two anonymous referees for their helpful comments that led to substantial improvements of the paper. The work of the first author was partially supported by a FP7 Marie Curie Career Integration Grant (PCIG11-GA-2012-321698 SOC-MP-ES) and by the Cyprus Program at MIT Energy Initiative. The work of the second author was supported by the U.S. National Science Foundation Grant No. 1128147 and by the US Department of Energy Office of Science, Biological and Environmental Research Program, Integrated Assessment Research Program, Grant Nos. DE-SC0005171 and DE-SC0003906.
PY - 2014
Y1 - 2014
N2 - Long-term planning for electric power systems, or capacity expansion, has traditionally been modeled using simplified models or heuristics to approximate the short-term dynamics. However, current trends such as increasing penetration of intermittent renewable generation and increased demand response requires a coupling of both the long and short term dynamics. We present an efficient method for coupling multiple temporal scales using the framework of singular perturbation theory for the control of Markov processes in continuous time. We show that the uncertainties that exist in many energy planning problems, in particular load demand uncertainty and uncertainties in generation availability, can be captured with a multiscale model. We then use a dimensionality reduction technique, which is valid if the scale separation present in the model is large enough, to derive a computationally tractable model. We show that both wind data and electricity demand data do exhibit sufficient scale separation. A numerical example using real data and a finite difference approximation of the Hamilton-Jacobi-Bellman equation is used to illustrate the proposed method. We compare the results of our approximate model with those of the exact model. We also show that the proposed approximation outperforms a commonly used heuristic used in capacity expansion models.
AB - Long-term planning for electric power systems, or capacity expansion, has traditionally been modeled using simplified models or heuristics to approximate the short-term dynamics. However, current trends such as increasing penetration of intermittent renewable generation and increased demand response requires a coupling of both the long and short term dynamics. We present an efficient method for coupling multiple temporal scales using the framework of singular perturbation theory for the control of Markov processes in continuous time. We show that the uncertainties that exist in many energy planning problems, in particular load demand uncertainty and uncertainties in generation availability, can be captured with a multiscale model. We then use a dimensionality reduction technique, which is valid if the scale separation present in the model is large enough, to derive a computationally tractable model. We show that both wind data and electricity demand data do exhibit sufficient scale separation. A numerical example using real data and a finite difference approximation of the Hamilton-Jacobi-Bellman equation is used to illustrate the proposed method. We compare the results of our approximate model with those of the exact model. We also show that the proposed approximation outperforms a commonly used heuristic used in capacity expansion models.
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U2 - 10.1016/j.ejor.2013.07.022
DO - 10.1016/j.ejor.2013.07.022
M3 - Article
AN - SCOPUS:84883797041
SN - 0377-2217
VL - 232
SP - 359
EP - 374
JO - European Journal of Operational Research
JF - European Journal of Operational Research
IS - 2
ER -