1、无线传感器网络模型设计英文文献翻译精说课讲解Model Design of Wireless Sensor Network based on Scale-Free Network TheoryABSTRACTThe key issue of researches on wireless sensor networks is to balance the energy costs across the whole network and to enhance the robustness in order to extend the survival time of the whole sens
2、or network. As a special complex network limited especially by the environment, sensor network is much different from the traditional complex networks, such as Internet network, ecological network, social network and etc. It is necessary to introduce a way of how to study wireless sensor network by
3、complex network theory and analysis methods, the key of which lies in a successful modeling which is able to make complex network theory and analysis methods more suitable for the application of wireless sensor network in order to achieve the optimization of some certain network characteristics of w
4、ireless sensor network. Based on generation rules of traditional scale-free networks, this paper added several restrictions to the improved model. The simulation result shows that improvements made in this paper have made the entire network have a better robustness to the random failure and the ener
5、gy costs are more balanced and reasonable. This improved model which is based on the complex network theory proves more applicable to the research of wireless sensor network.Key-words: Wireless sensor network; Complex network; Scale-free networkI. INTRODUCTIONIn recent years, wireless sensor network
6、s have attracted more and more related researchers for its advantages. Sensor nodes are usually low-power and non-rechargeable. The integrity of the original networks will be destroyed and other nodes will have more business burden for data transmission if the energy of some certain nodes deplete. T
7、he key issue of sensor network research is to balance the energy consumption of all sensor nodes and to minimize the impact of random failure of sensor nodes or random attacks to sensor nodes on the entire network 1.Complex network theory has been for some time since first proposed by Barabasi and A
8、lbert in 1998, but complex network theory and analysis method applied to wireless sensor networks research is seriously rare and develops in slow progress. As a special complex network limited especially by the environment, sensor network is much different from the traditional complex network, and t
9、he existing complex network theory and analysis methods can not be directly applied to analyze sensor networks. Based on scale-free network theory (BA model 2, (1 this paper added a random damage mechanism to each sensor node when deployed in the generation rule; (2 considering the real statement of
10、 wireless sensor networks, a minimum and maxinum restriction on sensor communication radius was added to each sensor node; (3 in order to maintain a balanced energy comsuption of the entire network, this paper added a limited degree of saturation value to each sensor node. This improved scale-free m
11、odel not only has the mentioned improvements above, but also has lots of advantages of traditional scale-free networks, such as the good ability to resist random attacks, so that the existing theory and analysis methods of complex network will be more suitable for the researches of wireless sensor n
12、etwork.II. PROGRESS OF RELATED RESEARCHHailin Zhu and Hong Luo have proposed two complex networks-based models for wireless sensor networks 3, the first of which named Energy-aware evolution model (EAEM can organize the networks in an energy-efficient way, and can produce scale-free networks which c
13、an improve the networks reliance against random failure of the sensor nodes. In the second model named Energy-balanced evolution model (EBEM, the maximum number of links for each node is introduced into the algorithm, which can make energy consumption more balanced than the previous model (EAEM.CHEN
14、 Lijun and MAO Yingchi have proposed a topology control of wireless sensor networks under an average degree constraint 4. In the precondition of the topology connectivity of wireless sensor networks, how to solve the sparseness of the network topology is a very important problem in a large number of
15、 sensor nodes deployed randomly. They proved their proposed scheme can decrease working nodes, guarantee network topology sparseness, predigest routing complexity and prolong network survival period.LEI Ming and LI Deshi have proposed a research on self-organization reliability of wireless sensor ne
16、twork5, which aiming on the two situations: deficiency of WSN nodes and under external attack, analyzes the error tolerance ability of different topologies of WSN, and eventually obtains optimized selforganized topological models of WSN and proposes a refined routing algorithm based on WSN.III. IMPR
17、OVED SCALE-FREE MODEL FOR WSNBecause of the limited energy and the evil application environment, wireless sensor networks may easily collapse when some certain sensor nodes are of energy depletion or destruction by the nature, and even some sensor nodes have been damaged when deployed. There is also
18、 a restriction on maxinum and mininum communication radius of sensor nodes rather than the other known scale-free networks such as Internet network, which has no restriction on communication radius. To have a balanced energy consumption, it is necessary to set up a saturation value limited degree of
19、 each sensor node 6.In response to these points, based on the traditional scale-free model, this paper has made the following improvements in the process of model establishment:(1 A large number of researches have shown that many complex networks in nature are not only the result from internal force
20、s, but also the result from external forces which should not be ignored to form an entire complex network. Node failure may not only occour by node energy depletion or random attacks to them when sensor networks are in the working progress, but also occour by external forces, such as by the nature,
21、when deployed. In this paper, a mechanism of small probability of random damage has been added to the formation of sensor networks.(2 Unlike Internet network where two nodes are able to connect directly to each other and their connection are never limited by their real location, sensor network, two
22、nodes in which connect to each other by the way of multi-hop, so that each node has a maximum of length restriction on their communication radius. To ensure the sparse of the whole network, there must also be a minimum of length restriction on their communication radius. In this paper, a length rest
23、riction on communication radius of sensor nodes has been proposed in the improved model.(3 In sensor network, if there exists a sensor node with a seriously high degree, whose energy consumption is very quickly, it will be seriously bad. The whole sensor network would surely collapse if enough energ
24、y were not supported to the certain node. To avoid this situation, this paper has set up a saturation value limited degree of each sensor node. By adding the mentioned restrictions above to the formation of the scale-free model, the new improved model will be more in line with the real statement of
25、sensor network. Complex network theory and analysis methods will be more appropriate when used to research and analyze the sensor network.IV . DESCRIPTION OF THE IMPROVED ALGORITHMThe specific algorithm of the improved model formation are described as follows :(1 A given region (assumed to be square
26、 is divided into HS*HSbig squares (named as BS;(2 Each BS (assumed to be square is divided into LS*LS small squares (named as SS, and each SS can have only one node in its coverage region;(3 m0 backbone nodes are initially generated as a random graph, and then a new node will be added to the network
27、 to connect the existing m nodes with m edges at each time interval. (m m0, mis a quantity parameter;(4 The newly generated node v, has a certain probability of Peto be damaged directly so that it will never be connected with any existing nodes;(5 The newly generated node vconnects with the existing
28、 node i, which obeyes dependent-preference rule and is surely limited by the degree of the certain saturation value .(6 The distance div between the newly generated node v connects and the existing node i shall be shorter than the maximum dmax of the communication radius of sensor nodes.Above all, t
29、he probability that the existing node i will be connected with the newly generated node v can be shown as follows:In order to compute it conveniently, here assumed that few nodes had reached the degree of saturation value kimax . That is, N is very minimal in Eqs.(1 so that it can be ignored here. A
30、nd in Eqs.iN j 1ak Kj=0N=m 1t +- (2With The varying rate with time of ki, we get:0m 112i i i i t jj k amk amk m t mt m k +-=- (3When t,condition: k i (t i =m, we get the solution: i 2,i t k t a=(t =m (4 The probability that the degree of node I is smaller than k is:11k (tkPt i i m t P k (5The time i
31、nterval when each newly generated node connected into the network is equal, so that probability density of t i is a constant parameter:01(t i P m t=+1/ we replace it into Eqs. (5, then we get:11111k (tkPt 1(t i m t k i i i t m t P P k =- (61101(t m m t k -+ So we get: 110(k (tk21(k.i P m t P k m t k
32、 =+ (7 When t , we get:2(k2m r P k -= (8 In which 12=1+=1+a , and the degree distribution we get and the degree distribution of traditional scale-free network are similar. Approximately, it has nothing to do with the time parameter t and the quantity of edges m generated at each time interval.max Pd d iv could be calculated by the max in um restriction dmax on communicationradius of each sensor node and the area of the entire coverage region S, thatis max Pd d iv =2Sd Then we replace max Pd d iv =2S d and a=max
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