Abstract
As detailed in Chap. 5, GEP is, in fact, the process of determining the generation requirements for a system so that the loads can be satisfied in an efficient (typically the most economical) manner while various technical or non-technical constraints are met. The approach presented in Chap. 5 was based on single bus representation of the system. In other words, we basically ignored the transmission system and found out the total generation requirements based on an optimization model.
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- 1.
Think of an alternative index in which the number of generation units is, somehow, accounted for.
- 2.
γ is the average cost per unit length of a line.
- 3.
b i is expressed in terms of loading of an overloaded line. If for instance, the capacity of a line is 200 MVA and its loading is 240 MVA, b i is 1.2.
References
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The references addressed for this chapter are the same as those introduced in Chap. 5. [1] is a reference book about power system reliability evaluation. [2] introduces WASP, the package developed by IAEA for GEP. [3] covers some practical issues for GEP in France at the time of publication. The economic parameters affecting GEP are discussed in [4]. Some mathematical based algorithms for GEP are covered in [5–7], while some non-mathematical based ones are introduced in [8–10]. Review and comparison of these algorithms are given in [11, 12]. If GEP and TEP are to be analyzed together, the problem becomes highly complex. Some algorithms are covered in [13–19].
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Seifi, H., Sepasian, M.S. (2011). Multi-bus Generation Expansion Planning. In: Electric Power System Planning. Power Systems. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-17989-1_6
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