Multistability in lossy power grids and oscillator networks

Balestra, Chiara; Kaiser, Franz; Manik, Debsankha; Witthaut, Dirk

doi:10.1063/1.5122739

Cited by 15 publications

(9 citation statements)

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“…However, a large proportion of the work mentioned above relies on the lossless line assumption, namely, neglecting dissipation, voltage amplitude dynamics, and reactive power flows. Recently, there has been a common effort in trying to pursue a more realistic mathematical analysis of power grids, by incorporating reactive power flows [16,17], voltage amplitude dynamics [54,55], and dissipation [25,26]. Despite all this work, there is still no clear extension of the winding partition to the full active-reactive power flows, even though there are some notable related preliminary works [56,57].…”

Section: Discussionmentioning

confidence: 99%

“…The presence of cycles in the network can induce the existence of multiple solutions to the Dissipative Flow Network Problem (see Fig. 3 or [25]). We rigorously show here that winding vectors characterize these solutions for sufficiently moderate dissipation.…”

Section: Theorem 1 Consider the Dissipative Flow Networkmentioning

confidence: 99%

“…The importance of understanding the more realistic case of dissipative couplings motivated the early work by Sakaguchi and Kuramoto [23,24] and is still an active field of research. Recent numerical investigations [25,26] as well as analytical studies in regular systems [27][28][29] are beginning to shed light on a more A winding number q ∈ Z is associated to each equilibrium, counting the number of times its angles wind counterclockwise around the origin. The three dots (left) are equilibria of the spring network, labeled with their winding numbers q.…”

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confidence: 99%

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Multistability and anomalies in oscillator models of lossy power grids

Delabays¹,

Jafarpour²,

Bullo³

2022

Preprint

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The analysis of dissipatively coupled oscillators is a challenging problem with high stakes in actual applications, such as large scale physical systems. Many standard mathematical methods are not applicable to such systems, due to the lack of symmetry of the network induced by dissipative couplings. Here we emphasize that the synchronization of coupled oscillators can be equivalently interpreted as the problem of flow distribution over a network. Based on these equivalent interpretations, we demonstrate a close correspondence between multiple stable synchronous states and winding cells in systems of dissipatively coupled oscillators. The recently introduced notion of winding cells, associated to a graph, forms a natural winding partition of the n-torus and capture essential characteristics of synchronous states in lossless systems. Leveraging the winding partition of the n-torus, we provide algorithms to compute the synchronous solutions of general networks of coupled oscillators. Furthermore, we identify three paradoxical behaviors of lossy networked systems, to be contrasted with the behavior lossless systems. Namely, we show that loop flows and dissipation can increase the system's transfer capacity, and that dissipation can promote multistability.

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Section: Discussionmentioning

confidence: 99%

Section: Theorem 1 Consider the Dissipative Flow Networkmentioning

confidence: 99%

mentioning

confidence: 99%

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Multistability and anomalies in oscillator models of lossy power grids

Delabays¹,

Jafarpour²,

Bullo³

2022

Preprint

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show abstract

“…The importance of understanding the more realistic case of dissipative couplings motivated the early work by Sakaguchi and Kuramoto 25 , 26 and is still an active field of research. Recent numerical investigations 27 , 28 as well as analytical studies in regular systems 29 – 31 are beginning to shed light on a more in-depth understanding of dissipative networks. More generally, the extension of standard approaches to more realistic systems is gaining momentum in the fields of synchronization and complex networks 32 – 34 .…”

Section: Introductionmentioning

confidence: 99%

“…The mathematical challenges encountered when relaxing the lossless line assumption confined most of the literature to numerical investigations 27 , 28 .…”

Section: Introductionmentioning

confidence: 99%

Multistability and anomalies in oscillator models of lossy power grids

2022

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The analysis of dissipatively coupled oscillators is challenging and highly relevant in power grids. Standard mathematical methods are not applicable, due to the lack of network symmetry induced by dissipative couplings. Here we demonstrate a close correspondence between stable synchronous states in dissipatively coupled oscillators, and the winding partition of their state space, a geometric notion induced by the network topology. Leveraging this winding partition, we accompany this article with an algorithms to compute all synchronous solutions of complex networks of dissipatively coupled oscillators. These geometric and computational tools allow us to identify anomalous behaviors of lossy networked systems. Counterintuitively, we show that loop flows and dissipation can increase the system’s transfer capacity, and that dissipation can promote multistability. We apply our geometric framework to compute power flows on the IEEE RTS-96 test system, where we identify two high voltage solutions with distinct loop flows.

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