Resilience for stochastic systems interacting via a quasi-degenerate network

Nicoletti, Sara; Fanelli, Duccio; Zagli, Niccolò; Asllani, Malbor; Battistelli, Giorgio; Carletti, Timotéo; Chisci, Luigi; Innocenti, Giacomo; Livi, Roberto

doi:10.1063/1.5099538

Cited by 12 publications

(14 citation statements)

References 51 publications

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“…Recently, a set of systematic statistical studies has brought to light the fact that most real networks, including biological, ecological, social, transport, economic, etc. [5][6][7][8][9], possess a high level of non-normality with peculiar structural features. In this regard, it has been recently shown for autonomous systems in [7] that despite a negative Master Stability Function (MSF) [10] indicating a strictly stable fixed point, the orbits starting near such a state could escape from it, stabilizing in other equilibrium.…”

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confidence: 99%

Synchronization Dynamics in Non-Normal Networks: The Trade-Off for Optimality

Muolo

Carletti

Gleeson

et al. 2020

Entropy

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Synchronization is an important behavior that characterizes many natural and human made systems that are composed by several interacting units. It can be found in a broad spectrum of applications, ranging from neuroscience to power-grids, to mention a few. Such systems synchronize because of the complex set of coupling they exhibit, with the latter being modeled by complex networks. The dynamical behavior of the system and the topology of the underlying network are strongly intertwined, raising the question of the optimal architecture that makes synchronization robust. The Master Stability Function (MSF) has been proposed and extensively studied as a generic framework for tackling synchronization problems. Using this method, it has been shown that, for a class of models, synchronization in strongly directed networks is robust to external perturbations. Recent findings indicate that many real-world networks are strongly directed, being potential candidates for optimal synchronization. Moreover, many empirical networks are also strongly non-normal. Inspired by this latter fact in this work, we address the role of the non-normality in the synchronization dynamics by pointing out that standard techniques, such as the MSF, may fail to predict the stability of synchronized states. We demonstrate that, due to a transient growth that is induced by the structure’s non-normality, the system might lose synchronization, contrary to the spectral prediction. These results lead to a trade-off between non-normality and directedness that should be properly considered when designing an optimal network, enhancing the robustness of synchronization.

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confidence: 99%

Synchronization Dynamics in Non-Normal Networks: The Trade-Off for Optimality

Muolo

Carletti

Gleeson

et al. 2020

Entropy

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“…Even when a fixed point is linearly stable in a nonlinear system described by ordinary differential equations, if the corresponding Jacobian matrix is non-normal, a small but finite perturbation can transiently grow beyond the validity of the linear approximation and enter into the nonlinear regime, preventing the perturbation from decaying to zero. The discovery of this phenomenon has led to the thorough study of the spectral properties of non-normal matrices in the context of transient dynamics [2]; it has also inspired recent works on implications of non-normality for network and spatiotemporal dynamics [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17]. Given the common perception that linear dynamics are fully understood, the possibility of such transient growth offers interesting alternative interpretations for behavior usually attributed to nonlinearity, such as ignition dynamics in combustion and temporary activation of biochemical signals.…”

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confidence: 99%

Non-normality and non-monotonic dynamics in complex reaction networks

Nicolaou

Nishikawa

Nicholson

et al. 2020

Phys. Rev. Research

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Complex chemical reaction networks, which underlie many industrial and biological processes, often exhibit non-monotonic changes in chemical species concentrations. Such non-monotonic dynamics are in principle possible even in a linear model if the matrix defining the model is non-normal, as characterized by a necessarily non-orthogonal set of eigenvectors. However, the extent to which non-normality is responsible for non-monotonic behavior remains an open question. Here, using a master equation to model the reaction dynamics, we derive a general condition for observing non-monotonic dynamics of individual species, establishing that non-normality promotes non-monotonicity but is not a requirement for it. In contrast, we show that non-normality is a requirement for non-monotonic dynamics to be observed in the Rényi entropy. Using hydrogen combustion as an example application, we demonstrate that non-monotonic dynamics under experimental conditions are supported by a linear chain of connected components, at variance with the dominance of a single giant component observed in typical random reaction networks. The exact linearity of the master equation enables development of a rigorous theory and simulations for dynamical networks of unprecedented sizes (approaching 10 5 dynamical variables, even for a network of only 20 reactions and involving less than 100 atoms). Our conclusions are expected to hold for other combustion processes, and the general theory we develop is applicable to all chemical reaction networks, including biological ones.

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“…Non-normal networks appear ubiquitous, with strong non-normality having been found in food webs, transport, and biological, social, communication, and citation networks (22). In addition, we mention that, besides information transfer, non-normality turns out to be the key to explaining and understanding a variety of other equally important phenomena, for instance, the process of pattern formation in natural and biological systems (21,35), the selective amplification of cortical activity patterns in the brain (32), and the emergence of giant oscillations in noise-driven dynamical systems (36)(37)(38).…”

Section: Discussionmentioning

confidence: 99%

“…Also, noise could play an active role in the information transfer process as the input source of the communication channel. This change of perspective could lead to an information-theoretic interpretation of the findings in (36)(37)(38), wherein non-normality has been linked with the emergence of amplified oscillations in noise-driven interconnected nonlinear systems.…”

Section: Discussionmentioning

confidence: 99%

Efficient communication over complex dynamical networks: The role of matrix non-normality

et al. 2020

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In both natural and engineered systems, communication often occurs dynamically over networks ranging from highly structured grids to largely disordered graphs. To use, or comprehend the use of, networks as efficient communication media requires understanding of how they propagate and transform information in the face of noise. Here, we develop a framework that enables us to examine how network structure, noise, and interference between consecutive packets jointly determine transmission performance in complex networks governed by linear dynamics. Mathematically, normal networks, which can be decomposed into separate low-dimensional information channels, suffer greatly from readout noise. Most details of their wiring have no impact on transmission quality. Non-normal networks, however, can largely cancel the effect of noise by transiently amplifying select input dimensions while ignoring others, resulting in higher net information throughput. Our theory could inform the design of new communication networks, as well as the optimal use of existing ones.

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Resilience for stochastic systems interacting via a quasi-degenerate network

Cited by 12 publications

References 51 publications

Synchronization Dynamics in Non-Normal Networks: The Trade-Off for Optimality

Synchronization Dynamics in Non-Normal Networks: The Trade-Off for Optimality

Non-normality and non-monotonic dynamics in complex reaction networks

Efficient communication over complex dynamical networks: The role of matrix non-normality

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