2013
DOI: 10.1109/tpwrs.2013.2255317
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Branch Flow Model: Relaxations and Convexification—Part I

Abstract: We propose a branch flow model for the analysis and optimization of mesh as well as radial networks. The model leads to a new approach to solving optimal power flow (OPF) that consists of two relaxation steps. The first step eliminates the voltage and current angles and the second step approximates the resulting problem by a conic program that can be solved efficiently. For radial networks, we prove that both relaxation steps are always exact, provided there are no upper bounds on loads. For mesh networks, the… Show more

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Cited by 1,182 publications
(725 citation statements)
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“…Beyond mean value convergence from (25), the bound in (26) assures that h(q g T ) remains close to the optimum h(q g ) with high probability. According to the online convex optimization terminology, the algorithm in Table I enjoys sublinear regret [29].…”
Section: Propositionmentioning
confidence: 99%
“…Beyond mean value convergence from (25), the bound in (26) assures that h(q g T ) remains close to the optimum h(q g ) with high probability. According to the online convex optimization terminology, the algorithm in Table I enjoys sublinear regret [29].…”
Section: Propositionmentioning
confidence: 99%
“…Of course, if the recent efforts in convexifying the OPF problem (e.g. [39,40,41]) find general application then any such convergence issues would be obsolete. Another question of interest is convergence performance in degenerate cases.…”
Section: On Decentralized Schemes Convergencementioning
confidence: 99%
“…Considering the power flow direction as depicted in Figure 2. Equation (27) - (30) represents the DistFlow equations, which have been verified in [26,29]. The nodal voltage drop along a feeder is represented by (27).…”
Section: Network Constraintsmentioning
confidence: 98%
“…In the third category, the non-linear/non-convex items in the D-OPF problems are directly approximated or relaxed into linear/convex form. Thus, the D-OPF is formulated as linear programming [24,25]; or semidefinite programming (SDP) [26]; or second-order cone programming (SOCP) using either polar coordinates [27] or the DistFlow model [28,29] by several convex relaxations. The relaxed convex D-OPF preserves the accuracy of the power flow model while improving the solution efficiency, and thus, it has become more and more popular in recent years.…”
Section: Introductionmentioning
confidence: 99%