Cite this Article
Li Ting-Ting, Li Cheng-Ren, Wang Chen, He Fang-Jun, Zhou Guang-Ye, Sun Jing-Chang, Han Fei. Synchronization investigation of the network group constituted by the nearest neighbor networks under inner and outer synchronous couplings. Chinese Physics B, 2016, 25(12): 128902  
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Synchronization investigation of the network group constituted by the nearest neighbor networks under inner and outer synchronous couplings
Li Ting-Ting, Li Cheng-Ren†, , Wang Chen, He Fang-Jun, Zhou Guang-Ye, Sun Jing-Chang, Han Fei
School of Physics and Electronic Technology, Liaoning Normal University, Dalian 116029, China

 

† Corresponding author. E-mail: lshdg@sina.com

Project supported by the National Natural Science Foundation of China (Grant No. 11004092), the Natural Science Foundation of Liaoning Province, China (Grant Nos. 2015020079 and 201602455), and the Foundation of Education Department of Liaoning Province, China (Grant No. L201683665)

Abstract
Abstract

A new synchronization technique of inner and outer couplings is proposed in this work to investigate the synchronization of network group. Some Haken–Lorenz lasers with chaos behaviors are taken as the nodes to construct a few nearest neighbor complex networks and those sub-networks are also connected to form a network group. The effective node controllers are designed based on Lyapunov function and the complete synchronization among the sub-networks is realized perfectly under inner and outer couplings. The work is of potential applications in the cooperation output of lasers and the communication network.

PACS: 89.75.–k;05.45.Xt
Keyword:synchronization of network group;inner and outer couplings;Haken–Lorenz laser;nearest neighbor network
1. Introduction

In recent years, it was found that the complex network is ubiquitous in human society and nature and increasingly plays an important role in many fields, such as communication network, transportation network, and power grid, and so on.[16] Therefore, the investigations about the dynamics behaviors of a complex network, especially about the network synchronization (including inner synchronization and outer synchronization), attract more and more comprehensive attention.[711] For example, Huys et al. reported synchronization research of chaotic networks with multiple delays[12] and Poria et al. discussed spatiotemporal synchronization of coupled Ricker maps over a complex network.[13] Correspondingly, the various network synchronization methods have been proposed, for instance, projection synchronization, adaptive synchronization, sliding mode synchronization and backstepping synchronization method, etc.[14,15]

The works about complex network synchronization reported previously focus mainly on the synchronization among all nodes within the network[1618] (so-called inner synchronization) and on the synchronization between two complex networks (so-called outer synchronization).[1922] In practice, however, the dynamics characteristics among some sub-networks connected to each other are also needed to analyze in-depth. For example, it is an urgent problem how to obtain the synchronization relationship among local networks or between local network and global network in the all optical communication network. Furthermore, the technique adopted for the synchronization of network group is different from these used in the synchronization within a network or between networks. Hence, the synchronization investigation about the network group which is constituted by a few sub-networks has become a hot topic in many research and application fields.

However, the research about synchronization of lots of complex networks, i.e., the so-called network group, has just started. A few works have been reported, for example, Jalan investigated the impact of the interaction of nodes in a layer of a multiplex network on the dynamical behavior and cluster synchronization of these nodes in the other layers.[23] Singh studied the impact of multiplexing on the global phase synchronizability of different layers in the delayed coupled multiplex networks.[24] Therefore, the research on the dynamics behaviors of the network group, especially on the synchronization principle, is still needed to explore in depth. In our work, a novel technique for realizing the synchronization among multiple networks is proposed and the controller forms of the nodes in every complex network are determined based on Lyapunov stability theorem.[25] In order to demonstrate the effectiveness of our synchronization method, some Haken–Lorenz laser systems with chaos behaviors are selected as the nodes to construct a few nearest neighbor complex networks, at the same time, these sub-networks are also reconnected to form a network group. The complete synchronization among the sub-networks is realized perfectly under inner and outer couplings, which also indicates the work is of potential applications in the cooperation output of lasers and the communication network.

2. Synchronization mechanism of network group

In this section, the synchronization mechanism of complex networks within the network group will be investigated. Some nonlinear dynamics systems with chaos behaviors are taken as the notes to construct M sub-networks (M = 3, 4, …) and to form a network group under inner and outer couplings. Within each sub-network, there are N nodes (N = 1, 2, …). Hence, the state equations of the i-th node in the 1st sub-network and the q-th sub-network can be respectively described as follows:

where

and

are the state variables of node equations belonging to the 1st and q-th sub-networks, respectively, and f(·) : RnRn is the nonlinear continuous differential function. N is the node number of each sub-network and M is the network number of the group. The symbols p and q respectively denote different sub-networks in the network group. A = (aijq) ∈ RN×N and B = (bijq) ∈ RN×N are the inner and outer coupling matrices of the sub-networks, and here the matrix elements aijq and bijq are defined as follows: If there is a connection between the node i and the node j, aijq = 1 (ij); otherwise aijq = 0 (ij). Similarly, if there is a coupling between node j in sub-network p and node i in sub-network q, bijq = 1; otherwise bijq = 0. mq is the inner coupling strength of the sub-network q and gp is the outer coupling strength between the nodes within different sub-networks q and p.

In this work, the first sub-network is set as target network and the rest of the sub-networks within the network group will track and synchronize with the first one. Under inner and outer couplings, the dynamics equations Eq. (2) of the corresponding nodes at respective controlled sub-networks are rewritten as follows:

where uiq (t) are the node controllers within the q-th sub-network and the error equations between Eq. (1) and Eq. (3) are defined as

Then, the derivatives of errors can be obtained

For the network group constituted by the complex sub-networks, we select the Lyapunov function as

and the derivative of Lyapunov function is

Hence, we can gain:

Through choosing some appropriate node controllers in the q-th sub-network, the synchronization between the state variables belonging to different sub-networks q and p will be achieved while the conditions are satisfied.[26] Therefore, we design the node controllers as

Substituting Eq. (9) into Eq. (8), then the latter can be rewritten as

Based on Lipschitz condition,[14] that is, the following inequality will be satisfied while there exists a real number li > 0.

where

and

are time varying vectors. Therefore, equation (10) can be further written as

where the error eiq1 can be regarded as the same as that of ejq1 because both i and j are the serial numbers of nodes in the network group, i, j = 1, 2,…, N. Also, Lq1, Lq2, and Lq are all positive real numbers and we let Lq = Lq1 + Lq2 for convenience. Hence

where

It is known that the sums of all rows in the configuration matrices are equal to zero, because the matrices , and need to satisfy the dissipation condition, which leads to Ai1 = Aiq = Bi1 = Biq = 0. So the values of parameters m1, mq, g1, and gq can be adjusted to meet the conditions of the network group synchronization (in our simulations, the following parameters m1 = 0.02, m2 = 0.05, m3 = 0.2, m4 = 0.05, g1 = 0.05, g2 = 0.05, g3 = 0.05, and g4 = 0.05 are chosen). In other words, ≤ 0 once k is taken as large enough to satisfy Lqk + mqAiq + m1Ai1g1Bi1 + gqBiq ≤ 0 and according to Lyapunov stability theorem, the error equations between arbitrary two sub-networks will trend quickly to zero, implying that the synchronization of network group constituted by the complex sub-networks can be obtained perfectly. It is worth noting that, in the above discussion, the numbers of sub-networks and nodes within a sub-network can be chosen freely without any limitation, which indicates the synchronization technique of the network group proposed in our work is universal.

It can be found that the theoretic deduction in this section mainly focuses on a directed topology. In fact, this method can be applied in the synchronization of the network group with the bidirectional coupling as well. In this case, the state equations of the i-th nodes in the 1st sub-network and the q-th sub-network can be respectively rewritten as follows:

and the synchronization can be achieved by the similar method.

3. Numerical simulation

In our simulations, forty Haken–Lorenz laser chaotic systems with different initial values are taken as the nodes to construct four nearest neighbor networks and there are ten nodes in each sub-network. Haken–Lorenz laser system with chaos behavior can be expressed as follows:[27]

where x1, x2, and x3 are state variables and parameters a, r, and b are positive real constant. The Haken–Lorenz laser system will be in chaotic state when the parameters are set as a = 1.4235, b = 0.2778, and r = 43. The evolutions of state variables and the phase diagram are shown in Fig. 1 while the initial values of three state variables are chosen in the range [0, 1].

Fig. 1. Evolutions of three state variables (a) and phase diagram (b) of the chaotic Haken–Lorenz laser.

Figure 2(a) is the topology structure of the nearest network with 10 nodes and figure 1(b) is diagrammatic sketch of the network group constituted by four sub-networks under inner and outer couplings. What needs to be explained is that four sub-networks are the same in our work for convenience, i.e., they are all nearest networks with 10 nodes, meaning the inner coupling coefficient matrices of four sub-networks are also the same and can be expressed as

Fig. 2. Topology structure of sub-network (a) and structure sketch of network group (b).

Figure 3 shows all error evolutions of ten nodes between target sub-network 1 and three controlled sub-networks with time, in which the meaning of can be understood as follows: d means the dimension (d = 1, 2, 3) of node state variable of the Haken–Lorenz laser; q represents the controlled sub-network (q = 2, 3, 4) and the second subscript 1 describes the target sub-network; i denotes node (i = 1–10) within every sub-network.

Fig. 3. Error evolutions of ten nodes with time between (a) network 2 and network 1; (b) network 3 and network 1; (c) network 4 and network 1.

It can be found from Fig. 3 that the error curves will exhibit intense oscillations at the initial stage of evolutions, and tend to zero rapidly and keep zero after a transient oscillation (about 2.7 s) under the effective node controllers, even though the initial values of every Haken–Lorenz lasers at different nodes are diverse, indicating that the synchronization technique proposed in our work is effective.

Hence, it can be seen from Fig. 3, due to the imposed controllers in the controlled network nodes, all errors after transient oscillations all trend to zero quickly, which means that this section of the proposed synchronization scheme is effective.

4. Conclusion

In this paper, a new synchronization technique of inner and outer couplings is proposed in order to investigate the synchronization of the network group. The effective node controllers are designed based on Lyapunov function and the complete synchronization among the sub-networks is realized perfectly under inner and outer couplings. For validating the effectiveness of our synchronization method, forty Haken–Lorenz lasers with chaotic behaviors are taken as the nodes to construct four nearest neighbor complex networks and those sub-networks are also connected to form a network group. The simulation results show that all error evolutions between target 1st sub-network and the controlled sub-network tend rapidly to zero after a transient oscillation even though the initial values of all Haken–Lorenz lasers at every nodes are different, which means the synchronization technique proposed in our work is effective. This work is of potential application in the cooperation output of lasers and the communication network.

Reference
1Liu GLi Y SZhang X P 2013 Chin. Phys. 22 068901
2Li C GMaini P K 2005 J. Phys. A: Math. Gen. 38 9741
3Amani TJordi MAli KKaher T 2014 Chin. Phys. 23 046101
4Nicosia VDomenico M DLatora V 2014 Europhys. Lett. 106 58005
5Shi C HPeng Y FZhuo YTang J YLong K P 2012 Phys. Scr. 85 035803
6Li M HGuanS GLai C H 2010 New J. Phys. 12 103032
7Hu T CSun W G 2013 Phys. Scr. 87 015001
8Zhao J C 2013 Chin. Phys. 22 060506
9Dai HSi G QJia L XZhang Y B 2014 Phys. Scr. 89 075204
10Li K ZHe EZeng Z RXie Z G 2013 Chin. Phys. 22 070504
11Zhang Z ZZeng S YTang W YHu J LZeng S WNing W LQiu YWu H S 2012 Chin. Phys. 21 108701
12D’Huys OZeeb SJüngling THeiligenthal SYanchuk SKinzel W 2013 Europhys. Lett. 103 10013
13Poria SKhan M ANag M 2013 Phys. Scr. 88 015004
14Wang W PLi L XPeng H PXiao J HYang Y X 2014 Nonlinear Dyn. 76 591
15 LLi C RChen L S 2014 Nonlinear Dyn. 76 1633
16Luo QWu WLi L XYang Y XPeng H P2008Acta Phys. Sin.571529(in Chinese)
17 LZhang C2009Acta Phys. Sin.581462(in Chinese)
18Zhang H GZhao MWang Z L 2014 Nonlinear Dyn. 77 643
19Jin Y GZhong S MAn N 2015 Chin. Phys. 24 049202
20Xu Y HZhou W NFang J ALu H Q 2009 Phys. Lett. 374 272
21Wei QXie X J 2015 Mod. Phys. 26 1550060
22Gu W FLiao X HZhang L SHuang X HHu GMi Y Y 2013 Europhys. Lett. 102 28001
23Jalan SSingh A 2016 Europhys. Lett. 113 30002
24Singh AGhosh SJalan Set al. 2015 Europhys. Lett. 111 30010
25Burgarth DGiovannetti V 2007 New J. Phys. 9 150
26Luo QYang HHan J XLi L XYang Y X 2010 J. Phys. A: Math. Theor. 43 495101
27Zhao J LWang JWang H 2012 Acta Phys. Sin. 61 110209 (in Chinese)