Power System Steady-State Estimation Revisited
In power system steady-state estimation (PSSE), one needs to consider (1) the need for robust statistics, (2) the nonconvex transmission constraints, (3) the fast-varying nature of the inputs, and the corresponding need to track optimal trajectories as closely as possible. In combination, these chal...
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| creator | Rytir, Pavel Wodecki, Ales Malachov, Martin Baxant, Pavel Vorac, Premysl Chladova, Miloslava Marecek, Jakub |
| description | In power system steady-state estimation (PSSE), one needs to consider (1) the
need for robust statistics, (2) the nonconvex transmission constraints, (3) the
fast-varying nature of the inputs, and the corresponding need to track optimal
trajectories as closely as possible. In combination, these challenges have not
been considered, yet. In this paper, we address all three challenges. The need
for robustness (1) is addressed by using an approach based on the so-called
Huber model. The non-convexity (2) of the problem, which results in first order
methods failing to find global minima, is dealt with by applying global
methods. One of these methods is based on a mixed integer quadratic
formulation, which provides results of several orders of magnitude better than
conventional gradient descent. Lastly, the trajectory tracking (3) is discussed
by showing under which conditions the trajectory tracking of the SDP
relaxations has meaning. |
| doi_str_mv | 10.48550/arxiv.2501.03400 |
| format | Article |
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need for robust statistics, (2) the nonconvex transmission constraints, (3) the
fast-varying nature of the inputs, and the corresponding need to track optimal
trajectories as closely as possible. In combination, these challenges have not
been considered, yet. In this paper, we address all three challenges. The need
for robustness (1) is addressed by using an approach based on the so-called
Huber model. The non-convexity (2) of the problem, which results in first order
methods failing to find global minima, is dealt with by applying global
methods. One of these methods is based on a mixed integer quadratic
formulation, which provides results of several orders of magnitude better than
conventional gradient descent. Lastly, the trajectory tracking (3) is discussed
by showing under which conditions the trajectory tracking of the SDP
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need for robust statistics, (2) the nonconvex transmission constraints, (3) the
fast-varying nature of the inputs, and the corresponding need to track optimal
trajectories as closely as possible. In combination, these challenges have not
been considered, yet. In this paper, we address all three challenges. The need
for robustness (1) is addressed by using an approach based on the so-called
Huber model. The non-convexity (2) of the problem, which results in first order
methods failing to find global minima, is dealt with by applying global
methods. One of these methods is based on a mixed integer quadratic
formulation, which provides results of several orders of magnitude better than
conventional gradient descent. Lastly, the trajectory tracking (3) is discussed
by showing under which conditions the trajectory tracking of the SDP
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need for robust statistics, (2) the nonconvex transmission constraints, (3) the
fast-varying nature of the inputs, and the corresponding need to track optimal
trajectories as closely as possible. In combination, these challenges have not
been considered, yet. In this paper, we address all three challenges. The need
for robustness (1) is addressed by using an approach based on the so-called
Huber model. The non-convexity (2) of the problem, which results in first order
methods failing to find global minima, is dealt with by applying global
methods. One of these methods is based on a mixed integer quadratic
formulation, which provides results of several orders of magnitude better than
conventional gradient descent. Lastly, the trajectory tracking (3) is discussed
by showing under which conditions the trajectory tracking of the SDP
relaxations has meaning.</abstract><doi>10.48550/arxiv.2501.03400</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Systems and Control Mathematics - Optimization and Control |
| title | Power System Steady-State Estimation Revisited |
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