Your search keyword '"Kurths, Jürgen"' showing total 196 results

1. Optimized multi-variable coupling can improve synchronization in complex networks

Author

Ansarinasab, Sheida, Parastesh, Fatemeh, Ghassemi, Farnaz, Rajagopal, Karthikeyan, Jafari, Sajad, and Kurths, Jürgen

Published

2024

2. Recurrence-based analysis and controlling switching between synchronous silence and bursting states of coupled generalized FitzHugh-Nagumo models driven by an external sinusoidal current

Author

Tagne Nkounga, Innocent Boris, Marwan, Norbert, Yamapi, René, and Kurths, Jürgen

Published

2024

3. Finite-time synchronization for fuzzy shunting inhibitory cellular neural networks.

Author

Nuriyev, Zhangir, Issakhanov, Alfarabi, Kurths, Jürgen, and Kashkynbayev, Ardak

Subjects

SYNCHRONIZATION, LYAPUNOV functions, PARTIAL differential equations, NONLINEAR differential equations

Abstract

Finite-time synchronization is a critical problem in the study of neural networks. The primary objective of this study was to construct feedback controllers for various models based on fuzzy shunting inhibitory cellular neural networks (FSICNNs) and find out the sufficient conditions for the solutions of those systems to reach synchronization in finite time. In particular, by imposing global assumptions of Lipschitz continuous and bounded activation functions, we prove the existence of finitetime synchronization for three basic FSICNN models that have not been studied before. Moreover, we suggest both controllers and Lyapunov functions that would yield a feasible convergence time between solutions that takes into account the chosen initial conditions. In general, we consecutively explore models of regular delayed FSICNNs and then consider them in the presence of either inertial or diffusion terms. Using criteria derived by means of the maximum-value approach in its different forms, we give an upper bound of the time up to which synchronization is guaranteed to occur in all three FSICNN models. These results are supported by 2D and 3D computer simulations and two respective numerical examples for 2 × 2 and 2 × 3 cases, which show the behavior of the solutions and errors under different initial conditions of FSICNNs in the presence and absence of designed controllers. [ABSTRACT FROM AUTHOR]

Published

2024

4. Precipitation over northern South America and the far‐eastern Pacific during ENSO: Phase synchronization at inter‐annual time scales.

Author

Salas, Hernán D., Builes‐Jaramillo, Alejandro, Boers, Niklas, Poveda, Germán, Mesa, Óscar J., and Kurths, Jürgen

Subjects

SOUTHERN oscillation, PRECIPITATION anomalies, EL Nino, RAINFALL anomalies, OCEAN temperature, PRECIPITATION variability

Abstract

We investigated the influence of the El Niño‐Southern Oscillation (ENSO) on inter‐annual precipitation variability in the far‐eastern Pacific (FEP) and northern South America (NSA) using an approach based on phase synchronization (PS). First, we carried out a detailed analysis of observational data to define the inter‐annual variability, eliminate the seasonal residual frequencies in hydro‐climatic anomalies, and assess the statistical significance of PS. Additionally, we characterized the seasonality of regional patterns of sea surface temperature, surface pressure levels, low‐level winds and precipitation anomalies associated with the ENSO states. We found that the positive (negative) precipitation anomalies experienced in the FEP and NSA differ from those previously reported in the literature. In particular, the Guianas (northeastern Amazon) and the Caribbean constitute two regions with negative (positive) rainfall anomalies during El Niño (La Niña), separated by a zone of non‐significant anomalies along the Orinoco Low‐level Jet corridor. Moreover, we showed that the ENSO signal is phase‐locked with inter‐annual rainfall and low‐level wind variability in most of the study regions. Furthermore, we found consistency in the PS between the Central and Eastern Pacific El Niño indices and hydroclimatic anomalies over the Pacific. However, some areas exhibited PS, although they did not show significant precipitation anomalies, suggesting that the influence of ENSO on tropical climatology manifests not only in terms of the magnitude of anomalies but also in terms of the phases only. Our approach advances the understanding of climatic anomalies in tropical regions and provides new insights into the non‐linear interactions between ENSO and hydroclimatic processes in tropical Americas. [ABSTRACT FROM AUTHOR]

Published

2024

5. Synchronization enhancement subjected to adaptive blinking coupling.

Author

Irankhah, Reza, Mehrabbeik, Mahtab, Parastesh, Fatemeh, Rajagopal, Karthikeyan, Jafari, Sajad, and Kurths, Jürgen

Subjects

CHAOS synchronization, SYNCHRONIZATION, COUPLING schemes, TIME-varying networks, COUPLINGS (Gearing)

Abstract

Synchronization holds a significant role, notably within chaotic systems, in various contexts where the coordinated behavior of systems plays a pivotal and indispensable role. Hence, many studies have been dedicated to investigating the underlying mechanism of synchronization of chaotic systems. Networks with time-varying coupling, particularly those with blinking coupling, have been proven essential. The reason is that such coupling schemes introduce dynamic variations that enhance adaptability and robustness, making them applicable in various real-world scenarios. This paper introduces a novel adaptive blinking coupling, wherein the coupling adapts dynamically based on the most influential variable exhibiting the most significant average disparity. To ensure an equitable selection of the most effective coupling at each time instance, the average difference of each variable is normalized to the synchronous solution's range. Due to this adaptive coupling selection, synchronization enhancement is expected to be observed. This hypothesis is assessed within networks of identical systems, encompassing Lorenz, Rössler, Chen, Hindmarsh–Rose, forced Duffing, and forced van der Pol systems. The results demonstrated a substantial improvement in synchronization when employing adaptive blinking coupling, particularly when applying the normalization process. [ABSTRACT FROM AUTHOR]

Published

2024

6. Synchronization stability and multi-timescale analysis of renewable-dominated power systems.

Author

Ma, Rui, Zhang, Yayao, Han, Miao, Kurths, Jürgen, and Zhan, Meng

Subjects

ELECTRIC power, SYNCHRONOUS generators, SYNCHRONIZATION, DIFFERENTIAL-algebraic equations, ALGEBRAIC equations, PHASE-locked loops, INDUCTION generators

Abstract

Synchronization is one of the key issues in three-phase AC power systems. Its characteristics have been dramatically changed with the large-scale integration of power-electronic-based renewable energy, mainly including a permanent magnetic synchronous generator (PMSG) and a double-fed induction generator (DFIG) for wind energy and a photovoltaic (PV) generator for solar energy. In this paper, we review recent progresses on the synchronization stability and multi-timescale properties of the renewable-dominated power system (RDPS), from nodes and network perspectives. All PMSG, DFIG, and PV are studied. In the traditional synchronous generator (SG) dominated power system, its dynamics can be described by the differential–algebraic equations (DAEs), where the dynamic apparatuses are modeled by differential equations and the stationary networks are described by algebraic equations. Unlike the single electromechanical timescale and DAE description for the SG-dominated power system, the RDPS dynamics should be described by the multiscale dynamics of both nodes and networks. For three different timescales, including the AC current control, DC voltage control, and rotor electromechanical timescales, their corresponding models are well established. In addition, for the multiscale network dynamics, the dynamical network within the AC current control timescale, which should be described by differential equations, can also be simplified as algebraic equations. Thus, the RDPS dynamics can be put into a similar DAE diagram for each timescale to the traditional power system dynamics, with which most of power electrical engineers are familiar. It is also found that the phase-locked loop for synchronization plays a crucial role in the whole system dynamics. The differences in the synchronization and multiscale characteristics between the traditional power system and the RDPS are well uncovered and summarized. Therefore, the merit of this paper is to establish a basic physical picture for the stability mechanism in the RDPS, which still lacks systematic studies and is controversial in the field of electrical power engineering. [ABSTRACT FROM AUTHOR]

Published

2023

7. Similar Master Stability Functions for Different Coupling Schemes in Basic Chaotic Systems.

Author

Dayani, Zahra, Parastesh, Fatemeh, Jafari, Sajad, Schöll, Eckehard, Kurths, Jürgen, and Sprott, Julien Clinton

Subjects

COUPLING schemes, ELECTRONIC information resource searching, DATABASE searching, SYNCHRONIZATION, IMAGE encryption

Abstract

Synchronization is a prominent phenomenon in coupled chaotic systems. The master stability function (MSF) is an approach that offers the prerequisites for the stability of complete synchronization, which is dependent on the coupling configuration. In this paper, some basic chaotic systems with the general form of the Sprott-A, Sprott-B, Sprott-D, Sprott-F, Sprott-G, Sprott-O, and Jerk systems are considered. For each system, their parametric form is designed, and constraints required to have similar MSFs in different coupling schemes are determined. Then, the parameters of the designed chaotic systems are found through an exhaustive computer search seeking chaotic solutions. The simplest cases found in this way are introduced, and similar synchronization patterns are confirmed numerically. [ABSTRACT FROM AUTHOR]

Published

2023

8. Criticality in transient behavior of coupled oscillator system toward chimera and synchronization.

Author

Yao, Nan, Zhang, Qian-Yun, Ren, De-Yi, Li, You-Jun, Su, Chun-Wang, Gao, Zhong-Ke, and Kurths, Jürgen

Subjects

SYNCHRONIZATION, DYNAMICAL systems, NUMERICAL analysis, BIOLOGICAL systems, PHENOMENOLOGICAL biology

Abstract

Chimera states in spatiotemporal dynamical systems have been investigated in physical, chemical, and biological systems, while how the system is steering toward different final destinies upon spatially localized perturbation is still unknown. Through a systematic numerical analysis of the evolution of the spatiotemporal patterns of multi-chimera states, we uncover a critical behavior of the system in transient time toward either chimera or synchronization as the final stable state. We measure the critical values and the transient time of chimeras with different numbers of clusters. Then, based on an adequate verification, we fit and analyze the distribution of the transient time, which obeys power-law variation process with the increase in perturbation strengths. Moreover, the comparison between different clusters exhibits an interesting phenomenon, thus we find that the critical value of odd and even clusters will alternatively converge into a certain value from two sides, respectively, implying that this critical behavior can be modeled and enabling the articulation of a phenomenological model. [ABSTRACT FROM AUTHOR]

Published

2023

9. Synchronization Induced by Layer Mismatch in Multiplex Networks.

Author

Anwar, Md Sayeed, Rakshit, Sarbendu, Kurths, Jürgen, and Ghosh, Dibakar

Subjects

SYNCHRONIZATION, SYNCHRONIC order

Abstract

Heterogeneity among interacting units plays an important role in numerous biological and man-made complex systems. While the impacts of heterogeneity on synchronization, in terms of structural mismatch of the layers in multiplex networks, has been studied thoroughly, its influence on intralayer synchronization, in terms of parameter mismatch among the layers, has not been adequately investigated. Here, we study the intralayer synchrony in multiplex networks, where the layers are different from one other, due to parameter mismatch in their local dynamics. In such a multiplex network, the intralayer coupling strength for the emergence of intralayer synchronization decreases upon the introduction of impurity among the layers, which is caused by a parameter mismatch in their local dynamics. Furthermore, the area of occurrence of intralayer synchronization also widens with increasing mismatch. We analytically derive a condition under which the intralayer synchronous solution exists, and we even sustain its stability. We also prove that, in spite of the mismatch among the layers, all the layers of the multiplex network synchronize simultaneously. Our results indicate that a multiplex network with mismatched layers can induce synchrony more easily than a multiplex network with identical layers. [ABSTRACT FROM AUTHOR]

Published

2023

10. Direction-dependent noise-induced synchronization in mobile oscillators.

Author

Shajan, Emilda, Ghosh, Dibakar, Kurths, Jürgen, and Shrimali, Manish Dev

Subjects

SYNCHRONIZATION, NONLINEAR oscillators, NOISE

Abstract

Synchronization among uncoupled oscillators can emerge when common noise is applied on them and is famously known as noise-induced synchronization. In previous studies, it was assumed that common noise may drive all the oscillators at the same time when they are static in space. Understanding how to develop a mathematical model that apply common noise to only a fraction of oscillators is of significant importance for noise-induced synchronization. Here, we propose a direction-dependent noise field model for noise-induced synchronization of an ensemble of mobile oscillators/agents, and the effective noise on each moving agent is a function of its direction of motion. This enables the application of common noise if the agents are oriented in the same direction. We observe not only complete synchronization of all the oscillators but also clustered states as a function of the ensemble density beyond a critical value of noise intensity, which is a characteristic of the internal dynamics of the agents. Our results provide a deeper understanding on noise-induced synchronization even in mobile agents and how the mobility of agents affects the synchronization behaviors. [ABSTRACT FROM AUTHOR]

Published

2023

11. Recurrence-Based Synchronization Analysis of Weakly Coupled Bursting Neurons under External ELF Fields

Author

Nkomidio, Aissatou Mboussi, Ngamga, Eulalie Ketchamen, Nbendjo, Blaise Romeo Nana, Kurths, Jürgen, and Marwan, Norbert

Subjects

gap junction, recurrence plot, ddc:530, weak coupling, 530 Physik, synchronization, neuron, electric field

Abstract

We investigate the response characteristics of a two-dimensional neuron model exposed to an externally applied extremely low frequency (ELF) sinusoidal electric field and the synchronization of neurons weakly coupled with gap junction. We find, by numerical simulations, that neurons can exhibit different spiking patterns, which are well observed in the structure of the recurrence plot (RP). We further study the synchronization between weakly coupled neurons in chaotic regimes under the influence of a weak ELF electric field. In general, detecting the phases of chaotic spiky signals is not easy by using standard methods. Recurrence analysis provides a reliable tool for defining phases even for noncoherent regimes or spiky signals. Recurrence-based synchronization analysis reveals that, even in the range of weak coupling, phase synchronization of the coupled neurons occurs and, by adding an ELF electric field, this synchronization increases depending on the amplitude of the externally applied ELF electric field. We further suggest a novel measure for RP-based phase synchronization analysis, which better takes into account the probabilities of recurrences.

Published

2022

12. Optimal time-varying coupling function can enhance synchronization in complex networks.

Author

Dayani, Zahra, Parastesh, Fatemeh, Nazarimehr, Fahimeh, Rajagopal, Karthikeyan, Jafari, Sajad, Schöll, Eckehard, and Kurths, Jürgen

Subjects

SYNCHRONIZATION, NEURAL circuitry, LYAPUNOV exponents, EIGENVALUES

Abstract

In this paper, we propose a time-varying coupling function that results in enhanced synchronization in complex networks of oscillators. The stability of synchronization can be analyzed by applying the master stability approach, which considers the largest Lyapunov exponent of the linearized variational equations as a function of the network eigenvalues as the master stability function. Here, it is assumed that the oscillators have diffusive single-variable coupling. All possible single-variable couplings are studied for each time interval, and the one with the smallest local Lyapunov exponent is selected. The obtained coupling function leads to a decrease in the critical coupling parameter, resulting in enhanced synchronization. Moreover, synchronization is achieved faster, and its robustness is increased. For illustration, the optimum coupling function is found for three networks of chaotic Rössler, Chen, and Chua systems, revealing enhanced synchronization. [ABSTRACT FROM AUTHOR]

Published

2023

13. Synchronization stability of power-grid-tied converters.

Author

Ma, Rui, Zhang, Yayao, Yang, Ziqian, Kurths, Jürgen, Zhan, Meng, and Lin, Congping

Subjects

SYNCHRONOUS generators, SYNCHRONIZATION, PHASE-locked loops, POWER electronics, DIFFERENTIAL equations, RENEWABLE energy sources

Abstract

Synchronization stability is one of central problems in power systems, and it is becoming much more complicated with the high penetration of renewable energy and power electronics devices. In this paper, we review recent work by several nonlinear models for renewable-dominated power systems in terms of multiple timescales, in particular, grid-tied converters within the DC voltage timescale. For the simplest model, a second-order differential equations called the generalized swing equation by considering only the phase-locked loop (PLL) is obtained, which shows a similar form with the well-known swing equation for a synchronous generator in the traditional power systems. With more outer controllers included, fourth-order and fifth-order models can be obtained. The fourth-order model is called the extended generalized swing equation, exhibiting the combined function of grid synchronization and active power balance on the DC capacitor. In addition, a nonlinear model for a two coupled converter system is given. Based on these studies, we find that the PLL plays a key role in synchronization stability. In summary, the value of this paper is to clarify the key concept of the synchronization stability in renewable-dominated power systems based on different nonlinear models, which still lacks systematic studies and is controversial in the field of electrical power engineering. Meanwhile, it clearly uncovers that the synchronization stability of converters has its root in the phase synchronization concept in nonlinear sciences. [ABSTRACT FROM AUTHOR]

Published

2023

14. Interconnection between the Indian and the East Asian summer monsoon: Spatial synchronization patterns of extreme rainfall events.

Author

Gupta, Shraddha, Su, Zhen, Boers, Niklas, Kurths, Jürgen, Marwan, Norbert, and Pappenberger, Florian

Subjects

RAINFALL, MONSOONS, MADDEN-Julian oscillation, ATMOSPHERIC circulation, PRECIPITATION forecasting, SYNCHRONIZATION

Abstract

A deeper understanding of the intricate relationship between the two components of the Asian summer monsoon (ASM)—the Indian summer monsoon (ISM) and the East Asian summer monsoon (EASM)—is crucial to improve the subseasonal forecasting of extreme precipitation events. Using an innovative complex network‐based approach, we identify two dominant synchronization pathways between ISM and EASM—a southern mode between the Arabian Sea and southeastern China occurring in June, and a northern mode between the core ISM zone and northern China which peaks in July—and their associated large‐scale atmospheric circulation patterns. Furthermore, we discover that certain phases of the Madden–Julian oscillation and the lower frequency mode of the boreal summer intraseasonal oscillation (BSISO) seem to favour the overall synchronization of extreme rainfall events between ISM and EASM while the higher‐frequency mode of the BSISO is likely to support the shifting between the modes of ISM–EASM connection. [ABSTRACT FROM AUTHOR]

Published

2023

15. Synchronization Analysis of Coupled Noncoherent Oscillators

Author

Kurths, Jürgen, Romano, M. Carmen, Thiel, Marco, Osipov, Grigory V., Ivanchenko, Mikhail V., Kiss, István Z., and Hudson, John L.

Published

2006

16. How heterogeneity in connections and cycles matter for synchronization of complex networks.

Author

Lacerda, Juliana C., Freitas, Celso, Macau, Elbert E. N., and Kurths, Jürgen

Subjects

SYNCHRONIZATION, HETEROGENEITY, MATHEMATICAL optimization

Abstract

We analyze how the structure of complex networks of non-identical oscillators influences synchronization in the context of the Kuramoto model. The complex network metrics assortativity and clustering coefficient are used in order to generate network topologies of Erdös–Rényi, Watts–Strogatz, and Barabási–Albert types that present high, intermediate, and low values of these metrics. We also employ the total dissonance metric for neighborhood similarity, which generalizes to networks the standard concept of dissonance between two non-identical coupled oscillators. Based on this quantifier and using an optimization algorithm, we generate Similar, Dissimilar, and Neutral natural frequency patterns, which correspond to small, large, and intermediate values of total dissonance, respectively. The emergency of synchronization is numerically studied by considering these three types of dissonance patterns along with the network topologies generated by high, intermediate, and low values of the metrics assortativity and clustering coefficient. We find that, in general, low values of these metrics appear to favor phase locking, especially for the Similar dissonance pattern. [ABSTRACT FROM AUTHOR]

Published

2021

17. Neuronal synchronization in long-range time-varying networks.

Author

Rakshit, Sarbendu, Majhi, Soumen, Kurths, Jürgen, and Ghosh, Dibakar

Subjects

TIME-varying networks, SYNCHRONIZATION, STRAIN hardening, NEURAL circuitry, SYNCHRONIC order

Abstract

We study synchronization in neuronal ensembles subject to long-range electrical gap junctions which are time-varying. As a representative example, we consider Hindmarsh–Rose neurons interacting based upon temporal long-range connections through electrical couplings. In particular, we adopt the connections associated with the direct 1 -path network to form a small-world network and follow-up with the corresponding long-range network. Further, the underlying direct small-world network is allowed to temporally change; hence, all long-range connections are also temporal, which makes the model much more realistic from the neurological perspective. This time-varying long-range network is formed by rewiring each link of the underlying 1 -path network stochastically with a characteristic rewiring probability p r , and accordingly all indirect k (> 1) -path networks become temporal. The critical interaction strength to reach complete neuronal synchrony is much lower when we take up rapidly switching long-range interactions. We employ the master stability function formalism in order to characterize the local stability of the state of synchronization. The analytically derived stability condition for the complete synchrony state agrees well with the numerical results. Our work strengthens the understanding of time-varying long-range interactions in neuronal ensembles. [ABSTRACT FROM AUTHOR]

Published

2021

18. Synchronization transition from chaos to limit cycle oscillations when a locally coupled chaotic oscillator grid is coupled globally to another chaotic oscillator.

Author

Godavarthi, Vedasri, Kasthuri, Praveen, Mondal, Sirshendu, Sujith, R. I., Marwan, Nobert, and Kurths, Jürgen

Subjects

LIMIT cycles, NONLINEAR oscillators, CHAOS synchronization, SYNCHRONIZATION, OSCILLATIONS, NUMERICAL control of machine tools, TURBULENT flow, POLYNOMIAL chaos

Abstract

Some physical systems with interacting chaotic subunits, when synchronized, exhibit a dynamical transition from chaos to limit cycle oscillations via intermittency such as during the onset of oscillatory instabilities that occur due to feedback between various subsystems in turbulent flows. We depict such a transition from chaos to limit cycle oscillations via intermittency when a grid of chaotic oscillators is coupled diffusively with a dissimilar chaotic oscillator. Toward this purpose, we demonstrate the occurrence of such a transition to limit cycle oscillations in a grid of locally coupled non-identical Rössler oscillators bidirectionally coupled with a chaotic Van der Pol oscillator. Further, we report the existence of symmetry breaking phenomena such as chimera states and solitary states during this transition from desynchronized chaos to synchronized periodicity. We also identify the temporal route for such a synchronization transition from desynchronized chaos to generalized synchronization via intermittent phase synchronization followed by chaotic synchronization and phase synchronization. Further, we report the loss of multifractality and loss of scale-free behavior in the time series of the chaotic Van der Pol oscillator and the mean field time series of the Rössler system. Such behavior has been observed during the onset of oscillatory instabilities in thermoacoustic, aeroelastic, and aeroacoustic systems. This model can be used to perform inexpensive numerical control experiments to suppress synchronization and thereby to mitigate unwanted oscillations in physical systems. [ABSTRACT FROM AUTHOR]

Published

2020

19. Spike chimera states and firing regularities in neuronal hypernetworks.

Author

Bera, Bidesh K., Rakshit, Sarbendu, Ghosh, Dibakar, and Kurths, Jürgen

Subjects

BRAIN function localization, NEURONS, BIOLOGICAL neural networks, SYNCHRONIZATION, PARAMETER estimation

Abstract

A complex spatiotemporal pattern with coexisting coherent and incoherent domains in a network of identically coupled oscillators is known as a chimera state. Here, we report the emergence and existence of a novel type of nonstationary chimera pattern in a network of identically coupled Hindmarsh–Rose neuronal oscillators in the presence of synaptic couplings. The development of brain function is mainly dependent on the interneuronal communications via bidirectional electrical gap junctions and unidirectional chemical synapses. In our study, we first consider a network of nonlocally coupled neurons where the interactions occur through chemical synapses. We uncover a new type of spatiotemporal pattern, which we call "spike chimera" induced by the desynchronized spikes of the coupled neurons with the coherent quiescent state. Thereafter, imperfect traveling chimera states emerge in a neuronal hypernetwork (which is characterized by the simultaneous presence of electrical and chemical synapses). Using suitable characterizations, such as local order parameter, strength of incoherence, and velocity profile, the existence of several dynamical states together with chimera states is identified in a wide range of parameter space. We also investigate the robustness of these nonstationary chimera states together with incoherent, coherent, and resting states with respect to initial conditions by using the basin stability measurement. Finally, we extend our study for the effect of firing regularity in the observed states. Interestingly, we find that the coherent motion of the neuronal network promotes the entire system to regular firing. [ABSTRACT FROM AUTHOR]

Published

2019

20. Bistable Firing Pattern in a Neural Network Model.

Author

Protachevicz, Paulo R., Borges, Fernando S., Lameu, Ewandson L., Ji, Peng, Iarosz, Kelly C., Kihara, Alexandre H., Caldas, Ibere L., Szezech, Jose D., Baptista, Murilo S., Macau, Elbert E. N., Antonopoulos, Chris G., Batista, Antonio M., and Kurths, Jürgen

Subjects

ARTIFICIAL neural networks, EPILEPSY, HYSTERESIS loop, BRAIN diseases

Abstract

Excessively high, neural synchronization has been associated with epileptic seizures, one of the most common brain diseases worldwide. A better understanding of neural synchronization mechanisms can thus help control or even treat epilepsy. In this paper, we study neural synchronization in a random network where nodes are neurons with excitatory and inhibitory synapses, and neural activity for each node is provided by the adaptive exponential integrate-and-fire model. In this framework, we verify that the decrease in the influence of inhibition can generate synchronization originating from a pattern of desynchronized spikes. The transition from desynchronous spikes to synchronous bursts of activity, induced by varying the synaptic coupling, emerges in a hysteresis loop due to bistability where abnormal (excessively high synchronous) regimes exist. We verify that, for parameters in the bistability regime, a square current pulse can trigger excessively high (abnormal) synchronization, a process that can reproduce features of epileptic seizures. Then, we show that it is possible to suppress such abnormal synchronization by applying a small-amplitude external current on > 10% of the neurons in the network. Our results demonstrate that external electrical stimulation not only can trigger synchronous behavior, but more importantly, it can be used as a means to reduce abnormal synchronization and thus, control or treat effectively epileptic seizures. [ABSTRACT FROM AUTHOR]

Published

2019

21. Neuron dynamics variability and anomalous phase synchronization of neural networks.

Author

Boaretto, B. R. R., Budzinski, R. C., Lopes, S. R., Prado, T. L., and Kurths, Jürgen

Subjects

NEURON analysis, CELL analysis, DYNAMICS, SYNCHRONIZATION, TIME measurements

Abstract

Anomalous phase synchronization describes a synchronization phenomenon occurring even for the weakly coupled network and characterized by a non-monotonous dependence of the synchronization strength on the coupling strength. Its existence may support a theoretical framework to some neurological diseases, such as Parkinson's and some episodes of seizure behavior generated by epilepsy. Despite the success of controlling or suppressing the anomalous phase synchronization in neural networks applying external perturbations or inducing ambient changes, the origin of the anomalous phase synchronization as well as the mechanisms behind the suppression is not completely known. Here, we consider networks composed of N = 2000 coupled neurons in a small-world topology for two well known neuron models, namely, the Hodgkin-Huxley-like and the Hindmarsh-Rose models, both displaying the anomalous phase synchronization regime. We show that the anomalous phase synchronization may be related to the individual behavior of the coupled neurons; particularly, we identify a strong correlation between the behavior of the inter-bursting-intervals of the neurons, what we call neuron variability, to the ability of the network to depict anomalous phase synchronization. We corroborate the ideas showing that external perturbations or ambient parameter changes that eliminate anomalous phase synchronization and at the same time promote small changes in the individual dynamics of the neurons, such that an increasing individual variability of neurons implies a decrease of anomalous phase synchronization. Finally, we demonstrate that this effect can be quantified using a well known recurrence quantifier, the "determinism." Moreover, the results obtained by the determinism are based on only the mean field potential of the network, turning these measures more suitable to be used in experimental situations. [ABSTRACT FROM AUTHOR]

Published

2018

22. Finite-Time Robust Synchronization of Memrisive Neural Network with Perturbation.

Author

Zhao, Hui, Li, Lixiang, Peng, Haipeng, Kurths, Jürgen, Xiao, Jinghua, and Yang, Yixian

Subjects

LYAPUNOV functions, LINEAR matrix inequalities, ARTIFICIAL neural networks, SYNCHRONIZATION, ROBUST control, MATHEMATICAL models

Abstract

In this paper, we study finite-time synchronization of a memristive neural network (MNN) with impulsive effect and stochastic perturbation. Because the parameters of the MNN are state-dependent, the traditional analytical method and control technique can not be directly used. In previous research, differential inclusions theory and set-valued mappings technique have been recently introduced to deal with this MNN system. But, we study the synchronization of MNN without using the previous solution technique. A novel analytical technique is first proposed to transform the MNN to a class of neural network (cNN) with uncertain parameters. The finite-time synchronization is obtained by disposing of parameter mismatch, impulsive effect or stochastic perturbation for the cNN. Several useful criteria of synchronization are obtained based on Lyapunov function, linear matrix inequality (LMI) and finite-time stability theory. Finally, two examples are given to demonstrate the effectiveness of our proposed method. [ABSTRACT FROM AUTHOR]

Published

2018

23. Exponential lag function projective synchronization of memristor-based multidirectional associative memory neural networks via hybrid control.

Author

Yuan, Manman, Wang, Weiping, Luo, Xiong, Li, Lixiang, Kurths, Jürgen, and Wang, Xiao

Subjects

EXPONENTIAL functions, SYNCHRONIZATION, MEMRISTORS, ASSOCIATIVE storage, ARTIFICIAL neural networks

Abstract

This paper is concerned with the exponential lag function projective synchronization of memristive multidirectional associative memory neural networks (MMAMNNs). First, we propose a new model of MMAMNNs with mixed time-varying delays. In the proposed approach, the mixed delays include time-varying discrete delays and distributed time delays. Second, we design two kinds of hybrid controllers. Traditional control methods lack the capability of reflecting variable synaptic weights. In this paper, the controllers are carefully designed to confirm the process of different types of synchronization in the MMAMNNs. Third, sufficient criteria guaranteeing the synchronization of system are derived based on the derive-response concept. Finally, the effectiveness of the proposed mechanism is validated with numerical experiments. [ABSTRACT FROM AUTHOR]

Published

2018

24. Publisher's Note: "Criticality in transient behavior of coupled oscillator system toward chimera and synchronization" [Chaos 33, 073131 (2023)].

Author

Yao, Nan, Zhang, Qian-Yun, Ren, De-Yi, Li, You-Jun, Su, Chun-Wang, Gao, Zhong-Ke, and Kurths, Jürgen

Subjects

NONLINEAR oscillators, SYNCHRONIZATION, PUBLISHING, MATHEMATICAL physics, SCIENCE projects

Abstract

2023-JC-YB-071, 2022JQ-010), Scientific Research Program Funded by Shaanxi Provincial Education Department (Program No. 22JP053), Shaanxi Fundamental Science Research Project for Mathematics and Physics (Grant No. 22JSQ037), NSFC of China (Grant No. 41975040), and the Taishan Industrial Experts Program. This work was supported by the National Key R&D Program of China under Grant No. 2021ZD0201300, the Project Supported by Natural Science Basic Research Plan in Shaanxi Province of China (Program Nos. This article was originally published online on 17 July 2023 with an error in the Acknowledgment section. [Extracted from the article]

Published

2023

25. Recovery time after localized perturbations in complex dynamical networks.

Author

Mitra, Chiranjit, Kittel, Tim, Choudhary, Anshul, Kurths, Jürgen, and Donner, Reik V.

Subjects

PERTURBATION theory, DYNAMICAL systems, RANDOM variables, SYNCHRONIZATION, TOPOLOGICAL property

Abstract

Maintaining the synchronous motion of dynamical systems interacting on complex networks is often critical to their functionality. However, real-world networked dynamical systems operating synchronously are prone to random perturbations driving the system to arbitrary states within the corresponding basin of attraction, thereby leading to epochs of desynchronized dynamics with a priori unknown durations. Thus, it is highly relevant to have an estimate of the duration of such transient phases before the system returns to synchrony, following a random perturbation to the dynamical state of any particular node of the network. We address this issue here by proposing the framework of single-node recovery time (SNRT) which provides an estimate of the relative time scales underlying the transient dynamics of the nodes of a network during its restoration to synchrony. We utilize this in differentiating the particularly slow nodes of the network from the relatively fast nodes, thus identifying the critical nodes which when perturbed lead to significantly enlarged recovery time of the system before resuming synchronized operation. Further, we reveal explicit relationships between the SNRT values of a network, and its global relaxation time when starting all the nodes from random initial conditions. Earlier work on relaxation time generally focused on investigating its dependence on macroscopic topological properties of the respective network. However, we employ the proposed concept for deducing microscopic relationships between topological features of nodes and their respective SNRT values. The framework of SNRT is further extended to a measure of resilience of the different nodes of a networked dynamical system. We demonstrate the potential of SNRT in networks of Rössler oscillators on paradigmatic topologies and a model of the power grid of the United Kingdom with second-order Kuramoto-type nodal dynamics illustrating the conceivable practical applicability of the proposed concept. [ABSTRACT FROM AUTHOR]

Published

2017

26. Global Stability of the Sync with Amplitude Effects.

Author

Shuai Liu, Wei Zou, MiaoZhuang He, Kurths, Jürgen, and Meng Zhan

Subjects

SYNCHRONIZATION, TIME measurements, NONLINEAR oscillators, AMPLITUDE modulation, COMPUTER simulation, SIMULATION methods & models

Abstract

Synchronization (or sync) is a basic problem in nature and engineering. One decade ago, the problem of the size of the sync (as a global geometric quantity) was first proposed by Wiley, Strogatz, and Girvan (WSG). In studying a ring of N coupled identical phase oscillators with each interacting equally with its d nearest neighbors on either side, they found that the sync state becomes globally stable when d/N is greater than a critical constant [D. A. Wiley, S. H. Strogatz, and M. Girvan, Chaos, 16 (2006) 015103]. Based on our previous results on the local stability of splay states in a ring of coupled Landau-Stuart oscillators, in this paper we further study the problem of global stability of the sync with amplitude effects, and we find that for any sufficiently large N the condition for the critical coupling range dc satisfying global stability of sync now becomes dc N ( γ= 2=3), whereas when the coupling strength becomes weaker, the condition gradually changes to dc = 0:3405N coincidental with the former result of the WSG in coupled phase oscillators. These relations are indicative of the favorable effect of amplitude for global stability of the sync. All these findings are based on rigorous theoretical analysis and have been well verified by numerical simulation; they are expected to be of potential significance for theory as well as application of synchronization in networked oscillatory systems. [ABSTRACT FROM AUTHOR]

Published

2017

27. Development of structural correlations and synchronization from adaptive rewiring in networks of Kuramoto oscillators.

Author

Lia Papadopoulos, Kim, Jason Z., Kurths, Jürgen, and Bassett, Danielle S.

Subjects

ELECTRIC oscillators, CHAOS synchronization, CHAOS theory, DIFFERENTIABLE dynamical systems, SYNCHRONIZATION

Abstract

Synchronization of non-identical oscillators coupled through complex networks is an important example of collective behavior, and it is interesting to ask how the structural organization of network interactions influences this process. Several studies have explored and uncovered optimal topologies for synchronization by making purposeful alterations to a network. On the other hand, the connectivity patterns of many natural systems are often not static, but are rather modulated over time according to their dynamics. However, this co-evolution and the extent to which the dynamics of the individual units can shape the organization of the network itself are less well understood. Here, we study initially randomly connected but locally adaptive networks of Kuramoto oscillators. In particular, the system employs a co-evolutionary rewiring strategy that depends only on the instantaneous, pairwise phase differences of neighboring oscillators, and that conserves the total number of edges, allowing the effects of local reorganization to be isolated. We find that a simple rule--which preserves connections between more out-of-phase oscillators while rewiring connections between more in-phase oscillators--can cause initially disordered networks to organize into more structured topologies that support enhanced synchronization dynamics. We examine how this process unfolds over time, finding a dependence on the intrinsic frequencies of the oscillators, the global coupling, and the network density, in terms of how the adaptive mechanism reorganizes the network and influences the dynamics. Importantly, for large enough coupling and after sufficient adaptation, the resulting networks exhibit interesting characteristics, including degree-frequency and frequency-neighbor frequency correlations. These properties have previously been associated with optimal synchronization or explosive transitions in which the networks were constructed using global information. On the contrary, by considering a time-dependent interplay between structure and dynamics, this work offers a mechanism through which emergent phenomena and organization can arise in complex systems utilizing local rules. [ABSTRACT FROM AUTHOR]

Published

2017

28. Multi-scale event synchronization analysis for unravelling climate processes: a wavelet-based approach.

Author

Agarwal, Ankit, Marwan, Norbert, Rathinasamy, Maheswaran, Merz, Bruno, and Kurths, Jürgen

Subjects

WAVELET transforms, MULTISCALE modeling, SYNCHRONIZATION, TIME series analysis, NONLINEAR theories

Abstract

The temporal dynamics of climate processes are spread across different timescales and, as such, the study of these processes at only one selected timescale might not reveal the complete mechanisms and interactions within and between the (sub-)processes. To capture the non-linear interactions between climatic events, the method of event synchronization has found increasing attention recently. The main drawback with the present estimation of event synchronization is its restriction to analysing the time series at one reference timescale only. The study of event synchronization at multiple scales would be of great interest to comprehend the dynamics of the investigated climate processes. In this paper, the wavelet-based multi-scale event synchronization (MSES) method is proposed by combining the wavelet transform and event synchronization. Wavelets are used extensively to comprehend multi-scale processes and the dynamics of processes across various timescales. The proposed method allows the study of spatio-temporal patterns across different timescales. The method is tested on synthetic and real-world time series in order to check its replicability and applicability. The results indicate that MSES is able to capture relationships that exist between processes at different timescales. [ABSTRACT FROM AUTHOR]

Published

2017

29. Effects of partial time delays on phase synchronization in Watts-Strogatz small-world neuronal networks.

Author

Xiaojuan Sun, Perc, Matjaž, and Kurths, Jürgen

Subjects

TIME delay systems, SYNCHRONIZATION, PARAMETER estimation, NEURONS, PROBABILITY theory

Abstract

In this paper, we study effects of partial time delays on phase synchronization in Watts-Strogatz small-world neuronal networks. Our focus is on the impact of two parameters, namely the time delay s and the probability of partial time delay pdelay, whereby the latter determines the probability with which a connection between two neurons is delayed. Our research reveals that partial time delays significantly affect phase synchronization in this system. In particular, partial time delays can either enhance or decrease phase synchronization and induce synchronization transitions with changes in the mean firing rate of neurons, as well as induce switching between synchronized neurons with period-1 firing to synchronized neurons with period-2 firing. Moreover, in comparison to a neuronal network where all connections are delayed, we show that small partial time delay probabilities have especially different influences on phase synchronization of neuronal networks. [ABSTRACT FROM AUTHOR]

Published

2017

30. Unraveling the primary mechanisms leading to synchronization response in dissimilar oscillators.

Author

Ramírez-Ávila, Gonzalo and Kurths, Jürgen

Subjects

*SYNCHRONIZATION, *ELECTRIC oscillators, *SYNCHRONIC order, *PICOSECOND pulses, *ULTRASHORT laser pulses

Abstract

We study how the phenomenon of response to synchronization arises in sets of pulse-coupled dissimilar oscillators. One of the sets is constituted by oscillators that can easily synchronize. Conversely, the oscillators of the other set do not synchronize. When the elements of the first set are not synchronized, they induce oscillation death in the constituents of the second set. By contrast, when synchronization is achieved in oscillators of the first set, those of the second set recover their oscillatory behavior and thus, responding to synchronization. Additionally, we found another interesting phenomenon in this type of systems, namely, a new control of simultaneous firings in a population of similar oscillators attained by means of the action of a dissimilar oscillator. [ABSTRACT FROM AUTHOR]

Published

2016

31. Experimental and modeling analysis of asymmetrical on-off oscillation in coupled non-identical inverted bottle oscillators.

Author

Ji Jia, Zhichun Shangguan, Haihong Li, Ye Wu, Weiqing Liu, Jinghua Xiao, and Kurths, Jürgen

Subjects

WATER bottles, VIBRATION (Mechanics), PRESSURE sensors, OSCILLATIONS, SYNCHRONIZATION

Abstract

Upside-down bottles containing water which are common in our daily life exhibit rich vibration dynamics. Rich dynamic regimes are observed in bottle oscillators by directly measuring the pressure difference between inside and outside of a bottle with the aid of pressure sensors. We observe experimentally that an asymmetrical oscillation process between the outflow of water and the inflow of air is formed in a single bottle oscillator and, in addition, a kind of 2:1 frequency synchronization occurs in a coupled system of two non-identical bottle oscillators. The peak values of the oscillation of pressure differences between inside and outside of the bottle decease as the height of the liquid surface steps down, while the oscillation period increases gradually. The theoretical model of the oscillator is amended to understand the regimes in the experiment by introducing time-dependent parameters related to the asymmetrical oscillation processes. Our numerical results based on the model fit well with the experimental ones. [ABSTRACT FROM AUTHOR]

Published

2016

32. Synchronization of mobile chaotic oscillator networks.

Author

Naoya Fujiwara, Kurths, Jürgen, and Díaz-Guilera, Albert

Subjects

*ELECTRIC oscillators, *CHAOS theory, *SYNCHRONIZATION, *UNCERTAINTY (Information theory), *LYAPUNOV exponents

Abstract

We study synchronization of systems in which agents holding chaotic oscillators move in a two-dimensional plane and interact with nearby ones forming a time dependent network. Due to the uncertainty in observing other agents' states, we assume that the interaction contains a certain amount of noise that turns out to be relevant for chaotic dynamics. We find that a synchronization transition takes place by changing a control parameter. But this transition depends on the relative dynamic scale of motion and interaction. When the topology change is slow, we observe an intermittent switching between laminar and burst states close to the transition due to small noise. This novel type of synchronization transition and intermittency can happen even when complete synchronization is linearly stable in the absence of noise. We show that the linear stability of the synchronized state is not a sufficient condition for its stability due to strong fluctuations of the transverse Lyapunov exponent associated with a slow network topology change. Since this effect can be observed within the linearized dynamics, we can expect such an effect in the temporal networks with noisy chaotic oscillators, irrespective of the details of the oscillator dynamics. When the topology change is fast, a linearized approximation describes well the dynamics towards synchrony. These results imply that the fluctuations of the finite-time transverse Lyapunov exponent should also be taken into account to estimate synchronization of the mobile contact networks. [ABSTRACT FROM AUTHOR]

Published

2016

33. Restoring oscillatory behavior from amplitude death with anti-phase synchronization patterns in networks of electrochemical oscillations.

Author

Nagao, Raphael, Wei Zou, Kurths, Jürgen, and Kiss, István Z.

Subjects

SYNCHRONIZATION, ELECTROCHEMISTRY, DYNAMICAL systems, THEORY of wave motion, ELECTRIC oscillators, PHASE oscillations

Abstract

The dynamical behavior of delay-coupled networks of electrochemical reactions is investigated to explore the formation of amplitude death (AD) and the synchronization states in a parameter region around the amplitude death region. It is shown that difference coupling with odd and even numbered ring and random networks can produce the AD phenomenon. Furthermore, this AD can be restored by changing the coupling type from difference to direct coupling. The restored oscillations tend to create synchronization patterns in which neighboring elements are in nearly anti-phase configuration. The ring networks produce frozen and rotating phase waves, while the random network exhibits a complex synchronization pattern with interwoven frozen and propagating phase waves. The experimental results are interpreted with a coupled Stuart-Landau oscillator model. The experimental and theoretical results reveal that AD behavior is a robust feature of delayed coupled networks of chemical units; if an oscillatory behavior is required again, even a small amount of direct coupling could be sufficient to restore the oscillations. The restored nearly anti-phase oscillatory patterns, which, to a certain extent, reflect the symmetry of the network, represent an effective means to overcome the AD phenomenon. [ABSTRACT FROM AUTHOR]

Published

2016

34. A common lag scenario in quenching of oscillation in coupled oscillators.

Author

Suresh, K., Sabarathinam, S., Thamilmaran, K., Kurths, Jürgen, and Dana, Syamal K.

Subjects

OSCILLATIONS, PARAMETERS (Statistics), TIME delay systems, SYNCHRONIZATION, LANDAU theory

Abstract

A large parameter mismatch can induce amplitude death in two instantaneously coupled oscillators. Alternatively, a time delay in the coupling can induce amplitude death in two identical oscillators. We unify the mechanism of quenching of oscillation in coupled oscillators, either by a large parameter mismatch or a delay coupling, by a common lag scenario that is, surprisingly, different from the conventional lag synchronization. We present numerical as well as experimental evidence of this unknown kind of lag scenario when the lag increases with coupling and at a critically large value at a critical coupling strength, amplitude death emerges in two largely mismatched oscillators. This is analogous to amplitude death in identical systems with increasingly large coupling delay. In support, we use examples of the Chua oscillator and the Bonhoeffer-van der Pol system. Furthermore, we confirm this lag scenario during the onset of amplitude death in identical Stuart- Landau system under various instantaneous coupling forms, repulsive, conjugate, and a type of nonlinear coupling. [ABSTRACT FROM AUTHOR]

Published

2016

35. Finite-Time Anti-synchronization Control of Memristive Neural Networks With Stochastic Perturbations.

Author

Wang, Weiping, Li, Lixiang, Peng, Haipeng, Kurths, Jürgen, Xiao, Jinghua, and Yang, Yixian

Subjects

MEMRISTORS, ELECTRIC resistors, SYNCHRONIZATION, TIME measurements, ARTIFICIAL neural networks

Abstract

In this paper, finite-time anti-synchronization control of memristive neural networks with stochastic perturbations is studied. We investigate a class of memristive neural networks with two different types of memductance functions. The purpose of the addressed problem is to design a nonlinear controller which can obtain anti-synchronization of the drive system and the response system in finite time. Based on two kinds of memductance functions, finite-time stability criteria are obtained for memristive neural networks with stochastic perturbations. The analysis in this paper employs differential inclusions theory, finite-time stability theorem, linear matrix inequalities and Lyapunov functional method. These theoretical analysis can characterize fundamental electrical properties of memristive systems and provide convenience for applications in pattern recognition, associative memories, associative learning, etc.. Finally, two numerical examples are given to show the effectiveness of our results. [ABSTRACT FROM AUTHOR]

Published

2016

36. Spatiotemporal characteristics and synchronization of extreme rainfall in South America with focus on the Andes Mountain range.

Author

Boers, Niklas, Bookhagen, Bodo, Marwan, Norbert, and Kurths, Jürgen

Subjects

RAINFALL, SPATIOTEMPORAL processes, NATURAL satellites, METEOROLOGICAL precipitation

Abstract

The South American Andes are frequently exposed to intense rainfall events with varying moisture sources and precipitation-forming processes. In this study, we assess the spatiotemporal characteristics and geographical origins of rainfall over the South American continent. Using high-spatiotemporal resolution satellite data (TRMM 3B42 V7), we define four different types of rainfall events based on their (1) high magnitude, (2) long temporal extent, (3) large spatial extent, and (4) high magnitude, long temporal and large spatial extent combined. In a first step, we analyze the spatiotemporal characteristics of these events over the entire South American continent and integrate their impact for the main Andean hydrologic catchments. Our results indicate that events of type 1 make the overall highest contributions to total seasonal rainfall (up to $$50\,\%$$ ). However, each consecutive episode of the infrequent events of type 4 still accounts for up to $$20\,\%$$ of total seasonal rainfall in the subtropical Argentinean plains. In a second step, we employ complex network theory to unravel possibly non-linear and long-ranged climatic linkages for these four event types on the high-elevation Altiplano-Puna Plateau as well as in the main river catchments along the foothills of the Andes. Our results suggest that one to two particularly large squall lines per season, originating from northern Brazil, indirectly trigger large, long-lasting thunderstorms on the Altiplano Plateau. In general, we observe that extreme rainfall in the catchments north of approximately $$20^{\circ }$$ S typically originates from the Amazon Basin, while extreme rainfall at the eastern Andean foothills south of $$20^{\circ }$$ S and the Puna Plateau originates from southeastern South America. [ABSTRACT FROM AUTHOR]

Published

2016

37. Spectral Analysis of Synchronization in Mobile Networks.

Author

Fujiwara, Naoya, Kurths, Jürgen, and Díaz-Guilera, Albert

Subjects

*SYNCHRONIZATION, *MOBILE communication systems, *COMPUTER networks, *TOPOLOGY, *EIGENVALUES

Abstract

We here analyze a system consisting of agents moving in a two-dimensional space that interact with other agents if they are within a finite range. Considering the motion and the interaction of the agents, the system can be understood as a network with a time-dependent topology. Dynamically, the agents are assumed to be identical oscillators, and the system will eventually reach a state of complete synchronization. In a previous work, we have shown that two qualitatively different mechanisms leading to synchronization in such mobile networks exist, namely global synchronization and local synchronization, depending on the parameters that characterize the oscillatory dynamics and the motion of the agents [1]. In this contribution we show that the spectral pattern differs between the two synchronization mechanisms. For global synchronization the spectrum is flat, which means that all eigenmodes contribute identically. For local synchronization, instead, the synchronization dynamics is determined mostly by the eigenmodes whose eigenvalues are close to zero. This result suggests that the global synchronization mechanism achieves fast synchronization by efficiently using the fast decaying eigenmodes (larger eigenvalues). [ABSTRACT FROM AUTHOR]

Published

2011

38. Weighted networks are more synchronizable: how and why.

Author

Motter, Adilson E., Changsong Zhou, and Kurths, Jürgen

Subjects

RANDOM dynamical systems, EIGENVALUES, SYNCHRONIZATION, MATHEMATICAL physics, SYSTEM analysis, HETEROGENEITY

Abstract

Most real-world networks display not only a heterogeneous distribution of degrees, but also a heterogeneous distribution of weights in the strengths of the connections. Each of these heterogeneities alone has been shown to suppress synchronization in random networks of dynamical systems. Here we review our recent findings that complete synchronization is significantly enhanced and becomes independent of both distributions when the distribution of weights is suitably combined with the distribution of degrees. We also present new results addressing the optimality of our findings and extending our analysis to phase synchronization in networks of non-identical dynamical unities. © 2005 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2005

39. Predicting Phase Synchronization for Homoclinic Chaos in a CO2 Laser.

Author

Tokuda, Isao, Kurths, Jürgen, Allaria, Enrico, Meucci, Riccardo, Boccaletti, Stefano, and Arecchi, F. Tito

Subjects

*SYNCHRONIZATION, *TIME measurements, *RECONSTRUCTION (U.S. history, 1865-1877), *INDUSTRIAL lasers, *PHYSICAL sciences, *LASERS

Abstract

A novel approach is presented for the reconstruction of phase synchronization phenomena in a chaotic CO2 laser from experimental data. We analyze this laser system in a regime of homoclinic chaos, which is able to phase synchronize with a weak sinusoidal forcing. Our technique recovers the synchronization diagram of the experimental system from only few measurement data sets, thus allowing the prediction of the regime of phase synchronization as well as non-synchronization in a broad parameter space of forcing frequency and amplitude without further experiments. © 2004 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2004

40. Chaos–order transition in foraging behavior of ants.

Author

Lixiang Li, Haipeng Peng, Kurths, Jürgen, Yixian Yang, and Schellnhuber, Hans Joachim

Subjects

FORAGING behavior, ANT behavior, PROBLEM solving, BIOLOGISTS, HUNTING, INSECT behavior

Abstract

The study of the foraging behavior of group animals (especially ants) is of practical ecological importance, but it also contributes to the development of widely applicable optimization problem-solving techniques. Biologists have discovered that single ants exhibit lowdimensional deterministic-chaotic activities. However, the influences of the nest, ants' physical abilities, and ants' knowledge (or experience) on foraging behavior have received relatively little attention in studies of the collective behavior of ants. This paper provides new insights into basic mechanisms of effective foraging for social insects or group animals that have a home. We propose that the whole foraging process of ants is controlled by three successive strategies: hunting, homing, and path building. A mathematical model is developed to study this complex scheme. We show that the transition from chaotic to periodic regimes observed in our model results from an optimization scheme for group animals with a home. According to our investigation, the behavior of such insects is not represented by random but rather deterministic walks (as generated by deterministic dynamical systems, e.g., by maps) in a random environment: the animals use their intelligence and experience to guide them. The more knowledge an ant has, the higher its foraging efficiency is.When young insects join the collective to forage with old and middle-aged ants, it benefits the whole colony in the long run. The resulting strategy can even be optimal. [ABSTRACT FROM AUTHOR]

Published

2014

41. SYNCHRONIZATION VIA PINNING CONTROL ON GENERAL COMPLEX NETWORKS.

Author

WENWU YU, GUANRONG CHEN, JINHU LÜ, and KURTHS, JÜRGEN

Subjects

COMPUTER networks, COLLECTIVE behavior, MANIFOLDS (Mathematics), MOBILE agent systems, ALGORITHMS

Abstract

This paper studies synchronization via pinning control on general complex dynamical networks, such as strongly connected networks, networks with a directed spanning tree, weakly connected networks, and directed forests. A criterion for ensuring network synchronization on strongly connected networks is given. It is found that the vertices with very small in-degrees should be pinned first. In addition, it is shown that the original condition with controllers can be reformulated such that it does not depend on the form of the chosen controllers, which implies that the vertices with very large out-degrees may be pinned. Then, a criterion for achieving synchronization on networks with a directed spanning tree, which can be composed of many strongly connected components, is derived. It is found that the strongly connected components with very few connections from other components should be controlled and the components with many connections from other components can achieve synchronization even without controls. Moreover, a simple but effective pinning algorithm for reaching synchronization on a general complex dynamical network is proposed. Finally, some simulation examples are given to verify the proposed pinning scheme. [ABSTRACT FROM AUTHOR]

Published

2013

42. A Constrained Evolutionary Computation Method for Detecting Controlling Regions of Cortical Networks.

Author

Tang, Yang, Wang, Zidong, Gao, Huijun, Swift, Stephen, and Kurths, Jürgen

Abstract

Controlling regions in cortical networks, which serve as key nodes to control the dynamics of networks to a desired state, can be detected by minimizing the eigenratio R and the maximum imaginary part \sigma of an extended connection matrix. Until now, optimal selection of the set of controlling regions is still an open problem and this paper represents the first attempt to include two measures of controllability into one unified framework. The detection problem of controlling regions in cortical networks is converted into a constrained optimization problem (COP), where the objective function R is minimized and \sigma is regarded as a constraint. Then, the detection of controlling regions of a weighted and directed complex network (e.g., a cortical network of a cat), is thoroughly investigated. The controlling regions of cortical networks are successfully detected by means of an improved dynamic hybrid framework (IDyHF). Our experiments verify that the proposed IDyHF outperforms two recently developed evolutionary computation methods in constrained optimization field and some traditional methods in control theory as well as graph theory. Based on the IDyHF, the controlling regions are detected in a microscopic and macroscopic way. Our results unveil the dependence of controlling regions on the number of driver nodes l and the constraint r. The controlling regions are largely selected from the regions with a large in-degree and a small out-degree. When r=+ \infty, there exists a concave shape of the mean degrees of the driver nodes, i.e., the regions with a large degree are of great importance to the control of the networks when l is small and the regions with a small degree are helpful to control the networks when l increases. When r=0, the mean degrees of the driver nodes increase as a function of l. We find that controlling \sigma is becoming more important in controlling a cortical network with increasing l. The methods and results of detecting controlling regions in this paper would promote the coordination and information consensus of various kinds of real-world complex networks including transportation networks, genetic regulatory networks, and social networks, etc. [ABSTRACT FROM PUBLISHER]

Published

2012

43. PINNING IMPULSIVE SYNCHRONIZATION OF COMPLEX DYNAMICAL NETWORKS.

Author

MAHDAVI, NARIMAN, MENHAJ, MOHAMMAD B., KURTHS, JÜRGEN, LU, JIANQUAN, and AFSHAR, AHMAD

Subjects

SYNCHRONIZATION, COMPUTER networks, TOPOLOGY, ALGORITHMS, ELECTRONIC controllers, SIMULATION methods & models, EXPONENTIAL functions

Abstract

In this paper, the problem of pinning impulsive synchronization for complex dynamical networks with directed or undirected but a strongly connected topology is investigated. To remedy this problem, we propose an efficient algorithm to find certain suitable nodes to be controlled via pinning and these selected nodes, in general, could be different at distinct impulsive time instants. The proposed algorithm guarantees the efficiency of the designed pinning impulsive strategy for the global exponential synchronization of state-coupled dynamical networks under an easily-verified condition. In other words, impulsive controllers and an efficient algorithm are designed to control a small fraction of the nodes, which successfully controls the whole dynamical network. Furthermore, we also estimate the upper bound of the number of pinning nodes, which is shown to be closely related to the impulsive intervals. The relationship implies that the required number of pinning nodes, which should be controlled for the successful control of the whole dynamical network, can be greatly reduced by reducing the impulses interval. Finally, simulations of scale-free and small-world networks are given to illustrate the effectiveness of the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2012

44. BIFURCATIONS IN A STAR-LIKE NETWORK OF STUART-LANDAU OSCILLATORS.

Author

FRASCA, MATTIA, BERGNER, ANDRÉ, KURTHS, JÜRGEN, and FORTUNA, LUIGI

Subjects

BIFURCATION theory, STAR-like functions, GRAPH theory, OSCILLATIONS, SYNCHRONIZATION, MATHEMATICAL forms

Abstract

In this paper, we analytically study a star motif of Stuart-Landau oscillators, derive the bifurcation diagram and discuss the different forms of synchronization arising in such a system. Despite the parameter mismatch between the central node and the peripheral ones, an analytical approach independent of the number of units in the system has been proposed. The approach allows to calculate the separatrices between the regions with distinct dynamical behavior and to determine the nature of the different transitions to synchronization appearing in the system. The theoretical analysis is supported by numerical results. [ABSTRACT FROM AUTHOR]

Published

2012

45. Synchronization of multi-frequency noise-induced oscillations.

Author

Astakhov, Sergey, Feoktistov, Alexey, Anishchenko, Vadim S., and Kurths, Jürgen

Subjects

SYNCHRONIZATION, NOISE, OSCILLATIONS, BIFURCATION theory, NEUROSCIENCES, NEURONS, MATHEMATICAL models

Abstract

Using a model system of FitzHugh-Nagumo type in the excitable regime, the similarity between synchronization of self-sustained and noise-induced oscillations is studied for the case of more than one main frequency in the spectrum. It is shown that this excitable system undergoes the same frequency lockings as a self-sustained quasiperiodic oscillator. The presence of noise-induced both stable and unstable limit cycles and tori, as well as their tangential bifurcations, are discussed. As the FitzHugh-Nagumo oscillator represents one of the basic neural models, the obtained results are of high importance for neuroscience. [ABSTRACT FROM AUTHOR]

Published

2011

46. Multiobjective synchronization of coupled systems.

Author

Tang, Yang, Wang, Zidong, Wong, W. K., Kurths, Jürgen, and Fang, Jian-an

Subjects

SYNCHRONIZATION, COUPLED mode theory (Wave-motion), CHAOS theory, STOCHASTIC convergence, MATHEMATICAL optimization, CODING theory, GENETIC algorithms, ARTIFICIAL neural networks

Abstract

In this paper, multiobjective synchronization of chaotic systems is investigated by especially simultaneously minimizing optimization of control cost and convergence speed. The coupling form and coupling strength are optimized by an improved multiobjective evolutionary approach that includes a hybrid chromosome representation. The hybrid encoding scheme combines binary representation with real number representation. The constraints on the coupling form are also considered by converting the multiobjective synchronization into a multiobjective constraint problem. In addition, the performances of the adaptive learning method and non-dominated sorting genetic algorithm-II as well as the effectiveness and contributions of the proposed approach are analyzed and validated through the Rössler system in a chaotic or hyperchaotic regime and delayed chaotic neural networks. [ABSTRACT FROM AUTHOR]

Published

2011

47. Burst synchronization transitions in a neuronal network of subnetworks.

Author

Sun, Xiaojuan, Lei, Jinzhi, Perc, Matjazˇ, Kurths, Jürgen, and Chen, Guanrong

Subjects

ARTIFICIAL neural networks, SYSTEM analysis, MATHEMATICAL models, NUMERICAL analysis, SYNCHRONIZATION, COUPLING constants, NEUROPLASTICITY

Abstract

In this paper, the transitions of burst synchronization are explored in a neuronal network consisting of subnetworks. The studied network is composed of electrically coupled bursting Hindmarsh-Rose neurons. Numerical results show that two types of burst synchronization transitions can be induced not only by the variations of intra- and intercoupling strengths but also by changing the probability of random links between different subnetworks and the number of subnetworks. Furthermore, we find that the underlying mechanisms for these two bursting synchronization transitions are different: one is due to the change of spike numbers per burst, while the other is caused by the change of the bursting type. Considering that changes in the coupling strengths and neuronal connections are closely interlaced with brain plasticity, the presented results could have important implications for the role of the brain plasticity in some functional behavior that are associated with synchronization. [ABSTRACT FROM AUTHOR]

Published

2011

48. Exponential Synchronization of Linearly Coupled Neural Networks With Impulsive Disturbances.

Author

Lu, Jianquan, Ho, Daniel W. C., Cao, Jinde, and Kurths, Jürgen

Subjects

SYNCHRONIZATION, ARTIFICIAL neural networks, TIME delay systems, MATRICES (Mathematics), MATHEMATICAL decomposition, EIGENFUNCTIONS, EIGENVALUES, SYMMETRIC matrices

Abstract

This brief investigates globally exponential synchronization for linearly coupled neural networks (NNs) with time-varying delay and impulsive disturbances. Since the impulsive effects discussed in this brief are regarded as disturbances, the impulses should not happen too frequently. The concept of average impulsive interval is used to formalize this phenomenon. By referring to an impulsive delay differential inequality, we investigate the globally exponential synchronization of linearly coupled NNs with impulsive disturbances. The derived sufficient condition is closely related with the time delay, impulse strengths, average impulsive interval, and coupling structure of the systems. The obtained criterion is given in terms of an algebraic inequality which is easy to be verified, and hence our result is valid for large-scale systems. The results extend and improve upon earlier work. As a numerical example, a small-world network composing of impulsive coupled chaotic delayed NN nodes is given to illustrate our theoretical result. [ABSTRACT FROM AUTHOR]

Published

2011

49. Bifurcation in neuronal networks with hub structure

Author

Kitajima, Hiroyuki and Kurths, Jürgen

Subjects

*BIFURCATION theory, *ARTIFICIAL neural networks, *SYSTEM analysis, *SYNCHRONIZATION, *COUPLED mode theory (Wave-motion)

Abstract

Abstract: We investigate bifurcations in neuronal networks with a hub structure. It is known that hubs play a leading role in characterizing the network dynamical behavior. However, the dynamics of hubs or star-coupled systems is not well understood. Here, we study rather subnetworks with a star-like configuration. This coupled system is an important motif in complex networks. Thus, our study is a basic step for understanding structure formation in large networks. We use the Morris–Lecar neuron with class I and class II excitabilities as a node. Homogeneous (coupling the same class neurons) and heterogeneous (coupling different class neurons) cases are considered for both excitatory and inhibitory coupling. For the homogeneous system class II neurons are suitable for achieving both complete and cluster synchronization in excitatory and inhibitory coupling, respectively. For the heterogeneous system with inhibitory coupling, the class I hub neuron has a wider parameter region of synchronous firings than the class II hub. Moreover, the class I hub neuron with the excitatory synapse gives rise to bifurcations of synchronized states and multi-stability (coexistence of a few different states) is observed. [Copyright &y& Elsevier]

Published

2009

50. Outer synchronization of coupled discrete-time networks.

Author

Changpin Li, Congxiang Xu, Weigang Sun, Jian Xu, and Kurths, Jürgen

Subjects

SYNCHRONIZATION, DISCRETE-time systems, LINEAR time invariant systems, SYSTEM analysis, TOPOLOGY, MATRICES (Mathematics), MATRIX groups, COMPLEX matrices, MATHEMATICS

Abstract

In this paper, synchronization between two discrete-time networks, called “outer synchronization” for brevity, is theoretically and numerically studied. First, a sufficient criterion for this outer synchronization between two coupled discrete-time networks which have the same connection topologies is derived analytically. Numerical examples are also given and they are in line with the theoretical analysis. Additionally, numerical investigations of two coupled networks which have different connection topologies are analyzed as well. The involved numerical results show that these coupled networks with different connection matrices can reach synchronization. [ABSTRACT FROM AUTHOR]

Published

2009