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Power Flow Analysis Using Graph based Combination of Iterative Methods and Vertex Contraction Approach

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arxiv 1809.01398 v1 pith:O4JAY6IA submitted 2018-09-05 cs.DC cs.DBcs.DScs.NAcs.PFmath.NA

Power Flow Analysis Using Graph based Combination of Iterative Methods and Vertex Contraction Approach

classification cs.DC cs.DBcs.DScs.NAcs.PFmath.NA
keywords graphdatabasepoweriterativemethodsproposedsystemanalysis
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Compared with relational database (RDB), graph database (GDB) is a more intuitive expression of the real world. Each node in the GDB is a both storage and logic unit. Since it is connected to its neighboring nodes through edges, and its neighboring information could be easily obtained in one-step graph traversal. It is able to conduct local computation independently and all nodes can do their local work in parallel. Then the whole system can be maximally analyzed and assessed in parallel to largely improve the computation performance without sacrificing the precision of final results. This paper firstly introduces graph database, power system graph modeling and potential graph computing applications in power systems. Two iterative methods based on graph database and PageRank are presented and their convergence are discussed. Vertex contraction is proposed to improve the performance by eliminating zero-impedance branch. A combination of the two iterative methods is proposed to make use of their advantages. Testing results based on a provincial 1425-bus system demonstrate that the proposed comprehensive approach is a good candidate for power flow analysis.

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