Bedogne' C, Rodgers G J
Department of Mathematical Sciences, Brunel University, Uxbridge, Middlesex UB8 3PH, United Kingdom.
Phys Rev E Stat Nonlin Soft Matter Phys. 2006 Oct;74(4 Pt 2):046115. doi: 10.1103/PhysRevE.74.046115. Epub 2006 Oct 23.
One of the major questions in complex network research is to identify the range of mechanisms by which a complex network can self organize into a scale-free state. In this paper we investigate the interplay between a fitness linking mechanism and both random and preferential attachment. In our models, each vertex is assigned a fitness x, drawn from a probability distribution rho(x). In Model A, at each time step a vertex is added and joined to an existing vertex, selected at random, with probability p and an edge is introduced between vertices with fitnesses x and y, with a rate f(x,y), with probability 1-p. Model B differs from Model A in that, with probability p, edges are added with preferential attachment rather than randomly. The analysis of Model A shows that, for every fixed fitness x, the network's degree distribution decays exponentially. In Model B we recover instead a power-law degree distribution whose exponent depends only on p, and we show how this result can be generalized. The properties of a number of particular networks are examined.
复杂网络研究中的一个主要问题是确定复杂网络能够自组织成无标度状态的机制范围。在本文中,我们研究了适应度链接机制与随机连接和偏好连接之间的相互作用。在我们的模型中,每个顶点被赋予一个适应度x,它从概率分布rho(x)中抽取。在模型A中,在每个时间步添加一个顶点,并以概率p随机选择一个现有顶点与之相连,并且以速率f(x,y)在适应度为x和y的顶点之间引入一条边,概率为1 - p。模型B与模型A的不同之处在于,以概率p,边通过偏好连接而不是随机添加。对模型A的分析表明,对于每个固定的适应度x,网络的度分布呈指数衰减。在模型B中,我们反而恢复了一个幂律度分布,其指数仅取决于p,并且我们展示了这个结果如何能够被推广。我们研究了一些特定网络的性质。
