Abstract
This paper examines the problem of state estimation in power distribution systems under low-observability conditions. The recently proposed constrained matrix completion method which combines the standard matrix completion method and power flow constraints has been shown to be effective in estimating voltage phasors under low-observability conditions using single-snapshot information. However, the method requires solving a semidefinite programming (SDP) problem, which becomes computationally infeasible for large systems and if multiple-snapshot (time-series) information is used. This paper proposes an efficient algorithm to solve the constrained matrix completion problem with time-series data. This algorithm is based on reformulating the matrix completion problem as a bilinear (non-convex) optimization problem, and applying the alternating minimization algorithm to solve this problem. This paper proves the summable convergence of the proposed algorithm, and demonstrates its efficacy and scalability via IEEE 123-bus system and a real utility feeder system. This paper also explores the value of adding more data from the history in terms of computation time and estimation accuracy.
Original language | American English |
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Number of pages | 9 |
State | Published - 2020 |
Event | IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (IEEE SmartGridComm) - Duration: 11 Nov 2020 → 13 Nov 2020 |
Conference
Conference | IEEE International Conference on Communications, Control, and Computing Technologies for Smart Grids (IEEE SmartGridComm) |
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Period | 11/11/20 → 13/11/20 |
Bibliographical note
See NREL/CP-5D00-79140 for paper as published in proceedingsNREL Publication Number
- NREL/CP-5D00-74961
Keywords
- alternating minimization
- distribution system state estimation
- matrix completion