介数中心性

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文件:Graph betweenness.svg
An undirected graph colored based on the betweenness centrality of each vertex from least (red) to greatest (blue).

An undirected graph colored based on the betweenness centrality of each vertex from least (red) to greatest (blue).

一个[根据每个顶点从最小(红色)到最大(蓝色)之间的中心性着色的无向图]

In graph theory, betweenness centrality is a measure of centrality in a graph based on shortest paths. For every pair of vertices in a connected graph, there exists at least one shortest path between the vertices such that either the number of edges that the path passes through (for unweighted graphs) or the sum of the weights of the edges (for weighted graphs) is minimized. The betweenness centrality for each vertex is the number of these shortest paths that pass through the vertex.

In graph theory, betweenness centrality is a measure of centrality in a graph based on shortest paths. For every pair of vertices in a connected graph, there exists at least one shortest path between the vertices such that either the number of edges that the path passes through (for unweighted graphs) or the sum of the weights of the edges (for weighted graphs) is minimized. The betweenness centrality for each vertex is the number of these shortest paths that pass through the vertex.

在图论中,中间中心性是基于最短路径的图中中心性的一种度量。对于连通图中的每一对顶点,在顶点之间至少存在一条最短路径,使得路径通过的边数(对于未加权图)或者边权重的和(对于加权图)最小。每个顶点的中心性是通过该顶点的最短路径的数量。


Betweenness centrality was devised as a general measure of centrality:模板:Sfnp it applies to a wide range of problems in network theory, including problems related to social networks, biology, transport and scientific cooperation. Although earlier authors have intuitively described centrality as based on betweenness, 模板:Harvp gave the first formal definition of betweenness centrality.

Betweenness centrality was devised as a general measure of centrality: it applies to a wide range of problems in network theory, including problems related to social networks, biology, transport and scientific cooperation. Although earlier authors have intuitively described centrality as based on betweenness, gave the first formal definition of betweenness centrality.

介于中心性被设计为中心性的一般衡量标准: 它适用于网络理论中的广泛问题,包括与社会网络、生物学、交通和科学合作有关的问题。尽管早期的作者直观地将中心性描述为基于中间性,但给出了中间性中心性的第一个正式定义。


Betweenness centrality finds wide application in network theory; it represents the degree to which nodes stand between each other. For example, in a telecommunications network, a node with higher betweenness centrality would have more control over the network, because more information will pass through that node.

Betweenness centrality finds wide application in network theory; it represents the degree to which nodes stand between each other. For example, in a telecommunications network, a node with higher betweenness centrality would have more control over the network, because more information will pass through that node.

介于中心性在网络理论中有着广泛的应用,它代表了节点之间相互站立的程度。例如,在电信网络中,具有较高中间中心性的节点将对网络有更多的控制,因为更多的信息将通过该节点。


Definition

The betweenness centrality of a node [math]\displaystyle{ v }[/math] is given by the expression:

The betweenness centrality of a node [math]\displaystyle{ v }[/math] is given by the expression:

一个节点 < math > v </math > 的中间中心性是通过表达式给出的:


[math]\displaystyle{ g(v)= \sum_{s \neq v \neq t}\frac{\sigma_{st}(v)}{\sigma_{st}} }[/math]

[math]\displaystyle{ g(v)= \sum_{s \neq v \neq t}\frac{\sigma_{st}(v)}{\sigma_{st}} }[/math]

< math > g (v) = sum _ { s neq v neq t } frac { sigma _ st }(v)}{ sigma _ st } </math >


where [math]\displaystyle{ \sigma_{st} }[/math] is the total number of shortest paths from node [math]\displaystyle{ s }[/math] to node [math]\displaystyle{ t }[/math] and [math]\displaystyle{ \sigma_{st}(v) }[/math] is the number of those paths that pass through [math]\displaystyle{ v }[/math].

where [math]\displaystyle{ \sigma_{st} }[/math] is the total number of shortest paths from node [math]\displaystyle{ s }[/math] to node [math]\displaystyle{ t }[/math] and [math]\displaystyle{ \sigma_{st}(v) }[/math] is the number of those paths that pass through [math]\displaystyle{ v }[/math].

其中 < math > sigma { st } </math > 是从节点 < math > s </math > 到节点 < math > t </math > 和 < math > sigma { st }(v) </math > 的最短路径总数。


Note that the betweenness centrality of a node scales with the number of pairs of nodes as suggested by the summation indices. Therefore, the calculation may be rescaled by dividing through by the number of pairs of nodes not including [math]\displaystyle{ v }[/math], so that [math]\displaystyle{ g \in [0,1] }[/math]. The division is done by [math]\displaystyle{ (N-1)(N-2) }[/math] for directed graphs and [math]\displaystyle{ (N-1)(N-2)/2 }[/math] for undirected graphs, where [math]\displaystyle{ N }[/math] is the number of nodes in the giant component. Note that this scales for the highest possible value, where one node is crossed by every single shortest path. This is often not the case, and a normalization can be performed without a loss of precision

Note that the betweenness centrality of a node scales with the number of pairs of nodes as suggested by the summation indices. Therefore, the calculation may be rescaled by dividing through by the number of pairs of nodes not including [math]\displaystyle{ v }[/math], so that [math]\displaystyle{ g \in [0,1] }[/math]. The division is done by [math]\displaystyle{ (N-1)(N-2) }[/math] for directed graphs and [math]\displaystyle{ (N-1)(N-2)/2 }[/math] for undirected graphs, where [math]\displaystyle{ N }[/math] is the number of nodes in the giant component. Note that this scales for the highest possible value, where one node is crossed by every single shortest path. This is often not the case, and a normalization can be performed without a loss of precision

注意,一个节点的中心性与节点对的数量成比例,如总和索引所示。因此,计算可以通过除以不包括 < math > v </math > 的节点对数来重新标度,这样 < math > g 在[0,1] </math > 中。有向图的除法是通过 < math > (N-1)(N-2) </math > 来完成的,而 < math > (N-1)(N-2)/2 </math > 的除法是通过无向图来完成的,其中 < math > n </math > 是巨型组件中的节点数。请注意,这可以缩放最大可能值,其中一个节点由每个最短路径交叉。事实往往并非如此,可以在不损失精度的情况下执行规范化

[math]\displaystyle{ \mbox{normal}(g(v)) = \frac{g(v) - \min(g)}{\max(g) - \min(g)} }[/math]

[math]\displaystyle{ \mbox{normal}(g(v)) = \frac{g(v) - \min(g)}{\max(g) - \min(g)} }[/math]

(g (v)) = frac { g (v)-min (g)}{ max (g)-min (g)} </math >

which results in:

which results in:

结果是:

[math]\displaystyle{ \max(normal) = 1 }[/math]

[math]\displaystyle{ \max(normal) = 1 }[/math]

Max (正常) = 1 </math >

[math]\displaystyle{ \min(normal) = 0 }[/math]

[math]\displaystyle{ \min(normal) = 0 }[/math]

< math > min (正常) = 0 </math >

Note that this will always be a scaling from a smaller range into a larger range, so no precision is lost.

Note that this will always be a scaling from a smaller range into a larger range, so no precision is lost.

请注意,这将始终是从较小范围缩放到较大范围的缩放,因此不会丢失精度。


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Weighted networks

In a weighted network the links connecting the nodes are no longer treated as binary interactions, but are weighted in proportion to their capacity, influence, frequency, etc., which adds another dimension of heterogeneity within the network beyond the topological effects. A node's strength in a weighted network is given by the sum of the weights of its adjacent edges.

In a weighted network the links connecting the nodes are no longer treated as binary interactions, but are weighted in proportion to their capacity, influence, frequency, etc., which adds another dimension of heterogeneity within the network beyond the topological effects. A node's strength in a weighted network is given by the sum of the weights of its adjacent edges.

在加权网络中,连接节点的链路不再被视为二元相互作用,而是根据其容量、影响力、频率等按比例加权,这在拓扑效应之外增加了网络内异质性的另一个维度。一个加权网络中的节点的强度是由其相邻边的权重之和来表示的。


[math]\displaystyle{ s_{i} = \sum_{j=1}^{N} a_{ij}w_{ij} }[/math]

[math]\displaystyle{ s_{i} = \sum_{j=1}^{N} a_{ij}w_{ij} }[/math]

[数学][数学][数学]


With [math]\displaystyle{ a_{ij} }[/math] and [math]\displaystyle{ w_{ij} }[/math] being adjacency and weight matrices between nodes [math]\displaystyle{ i }[/math] and [math]\displaystyle{ j }[/math], respectively.

With [math]\displaystyle{ a_{ij} }[/math] and [math]\displaystyle{ w_{ij} }[/math] being adjacency and weight matrices between nodes [math]\displaystyle{ i }[/math] and [math]\displaystyle{ j }[/math], respectively.

用 < math > a { ij } </math > 和 < math > w { ij } </math > 分别作为 < math > i </math > 和 < math > < j </math > 节点之间的邻接矩阵和权矩阵。

Analogous to the power law distribution of degree found in scale free networks, the strength of a given node follows a power law distribution as well.

Analogous to the power law distribution of degree found in scale free networks, the strength of a given node follows a power law distribution as well.

类似于无标度网络中度的幂律分布,给定节点的强度也服从幂律分布。


[math]\displaystyle{ s(k) \approx k^\beta }[/math]

[math]\displaystyle{ s(k) \approx k^\beta }[/math]

[ math ] s (k) approx k ^ beta [ math ]


A study of the average value [math]\displaystyle{ s(b) }[/math] of the strength for vertices with betweenness [math]\displaystyle{ b }[/math] shows that the functional behavior can be approximated by a scaling form [1]

A study of the average value [math]\displaystyle{ s(b) }[/math] of the strength for vertices with betweenness [math]\displaystyle{ b }[/math] shows that the functional behavior can be approximated by a scaling form

一项对具有介于数学之间的顶点强度的平均值的研究表明,函数行为可以用缩放形式来近似

[math]\displaystyle{ s(b)\approx b^{\alpha} }[/math]

[math]\displaystyle{ s(b)\approx b^{\alpha} }[/math]

S (b) approx b ^ { alpha } </math >


Percolation centrality

Percolation centrality is a version of weighted betweenness centrality, but it considers the 'state' of the source and target nodes of each shortest path in calculating this weight. Percolation of a ‘contagion’ occurs in complex networks in a number of scenarios. For example, viral or bacterial infection can spread over social networks of people, known as contact networks. The spread of disease can also be considered at a higher level of abstraction, by contemplating a network of towns or population centres, connected by road, rail or air links. Computer viruses can spread over computer networks. Rumours or news about business offers and deals can also spread via social networks of people. In all of these scenarios, a ‘contagion’ spreads over the links of a complex network, altering the ‘states’ of the nodes as it spreads, either recoverably or otherwise. For example, in an epidemiological scenario, individuals go from ‘susceptible’ to ‘infected’ state as the infection spreads. The states the individual nodes can take in the above examples could be binary (such as received/not received a piece of news), discrete (susceptible/infected/recovered), or even continuous (such as the proportion of infected people in a town), as the contagion spreads. The common feature in all these scenarios is that the spread of contagion results in the change of node states in networks. Percolation centrality (PC) was proposed with this in mind, which specifically measures the importance of nodes in terms of aiding the percolation through the network. This measure was proposed by Piraveenan et al.[2]

Percolation centrality is a version of weighted betweenness centrality, but it considers the 'state' of the source and target nodes of each shortest path in calculating this weight. Percolation of a ‘contagion’ occurs in complex networks in a number of scenarios. For example, viral or bacterial infection can spread over social networks of people, known as contact networks. The spread of disease can also be considered at a higher level of abstraction, by contemplating a network of towns or population centres, connected by road, rail or air links. Computer viruses can spread over computer networks. Rumours or news about business offers and deals can also spread via social networks of people. In all of these scenarios, a ‘contagion’ spreads over the links of a complex network, altering the ‘states’ of the nodes as it spreads, either recoverably or otherwise. For example, in an epidemiological scenario, individuals go from ‘susceptible’ to ‘infected’ state as the infection spreads. The states the individual nodes can take in the above examples could be binary (such as received/not received a piece of news), discrete (susceptible/infected/recovered), or even continuous (such as the proportion of infected people in a town), as the contagion spreads. The common feature in all these scenarios is that the spread of contagion results in the change of node states in networks. Percolation centrality (PC) was proposed with this in mind, which specifically measures the importance of nodes in terms of aiding the percolation through the network. This measure was proposed by Piraveenan et al.

渗透中心性是一种加权的介于中心性之间的中心性,但它在计算这个权重时考虑了每条最短路径的源节点和目标节点的状态。在许多情况下,复杂网络中都会出现“传染”现象。例如,病毒或细菌感染可以通过人们的社交网络传播,也就是所谓的接触网络。还可以在更高的抽象层次上考虑疾病的传播问题,设想通过公路、铁路或空中连接起来的城镇或人口中心网络。计算机病毒可以通过计算机网络传播。关于商业活动和交易的谣言或新闻也可以通过人们的社交网络传播。在所有这些情况下,一种“传染病”在一个复杂网络的链接上传播,随着它的传播,无论是可恢复的还是不可恢复的,都会改变节点的“状态”。例如,在流行病学方案中,随着感染扩散,个人从”易感”状态转变为”受感染”状态。在上面的例子中,每个节点可以采取的状态可以是二进制的(例如接收/没有接收到一条新闻)、离散的(易感/受感染/康复) ,甚至是连续的(例如一个城镇中受感染的人的比例) ,随着传染的扩散。这些情景的共同特点是,传染的扩散导致网络中节点状态的改变。渗滤中心性(PC)就是基于这个思想而提出的,它特别地衡量了节点在协助网络渗滤方面的重要性。这项措施是由 piraveanan 等人提出的。


Percolation centrality is defined for a given node, at a given time, as the proportion of ‘percolated paths’ that go through that node. A ‘percolated path’ is a shortest path between a pair of nodes, where the source node is percolated (e.g., infected). The target node can be percolated or non-percolated, or in a partially percolated state.

Percolation centrality is defined for a given node, at a given time, as the proportion of ‘percolated paths’ that go through that node. A ‘percolated path’ is a shortest path between a pair of nodes, where the source node is percolated (e.g., infected). The target node can be percolated or non-percolated, or in a partially percolated state.

过滤中心性定义为在给定时间内一个给定节点的过滤路径的比例。“渗滤路径”是一对节点之间的最短路径,其中源节点被渗滤(例如,被感染)。目标节点可以是过滤的或非过滤的,或处于部分过滤状态。


[math]\displaystyle{ PC^t(v)= \frac{1}{N-2}\sum_{s \neq v \neq r}\frac{\sigma_{sr}(v)}{\sigma_{sr}}\frac{{x^t}_s}{{\sum {[{x^t}_i}]}-{x^t}_v} }[/math]

[math]\displaystyle{ PC^t(v)= \frac{1}{N-2}\sum_{s \neq v \neq r}\frac{\sigma_{sr}(v)}{\sigma_{sr}}\frac{{x^t}_s}{{\sum {[{x^t}_i}]}-{x^t}_v} }[/math]

< math > PC ^ t (v) = frac {1}{ N-2} sum { s neq v neq r } frac { sigma { sr }(v)}{ sigma { sr }} frac { x ^ t }{ sum {[{ x ^ t } i }}}]}}-{ x ^ t }{ v } </math >


where [math]\displaystyle{ \sigma_{sr} }[/math] is total number of shortest paths from node [math]\displaystyle{ s }[/math] to node [math]\displaystyle{ r }[/math] and [math]\displaystyle{ \sigma_{sr}(v) }[/math] is the number of those paths that pass through [math]\displaystyle{ v }[/math]. The percolation state of the node [math]\displaystyle{ i }[/math] at time [math]\displaystyle{ t }[/math] is denoted by [math]\displaystyle{ {x^t}_i }[/math] and two special cases are when [math]\displaystyle{ {x^t}_i=0 }[/math] which indicates a non-percolated state at time [math]\displaystyle{ t }[/math] whereas when [math]\displaystyle{ {x^t}_i=1 }[/math] which indicates a fully percolated state at time [math]\displaystyle{ t }[/math]. The values in between indicate partially percolated states ( e.g., in a network of townships, this would be the percentage of people infected in that town).

where [math]\displaystyle{ \sigma_{sr} }[/math] is total number of shortest paths from node [math]\displaystyle{ s }[/math] to node [math]\displaystyle{ r }[/math] and [math]\displaystyle{ \sigma_{sr}(v) }[/math] is the number of those paths that pass through [math]\displaystyle{ v }[/math]. The percolation state of the node [math]\displaystyle{ i }[/math] at time [math]\displaystyle{ t }[/math] is denoted by [math]\displaystyle{ {x^t}_i }[/math] and two special cases are when [math]\displaystyle{ {x^t}_i=0 }[/math] which indicates a non-percolated state at time [math]\displaystyle{ t }[/math] whereas when [math]\displaystyle{ {x^t}_i=1 }[/math] which indicates a fully percolated state at time [math]\displaystyle{ t }[/math]. The values in between indicate partially percolated states ( e.g., in a network of townships, this would be the percentage of people infected in that town).

其中 < math > σ { sr } </math > 是从节点 < math > s </math > 到节点 < math > r </math > 和 < math > sigma { sr }(v) </math > 是通过 < math > v </math > 的路径的总数。在时间 < math > t </math > 时,节点的过滤状态用 < math > { x ^ t } _ i </math > 表示,两个特殊情况是当 < math > { x ^ t } _ i = 0 </math > 表示在时间上是非过滤状态,而当 < math > < x ^ t </math > i = 1 </math > 表示在时间上是完全过滤状态。两者之间的值表示部分过滤状态(例如,在一个城镇网络中,这是该城镇感染者的百分比)。


The attached weights to the percolation paths depend on the percolation levels assigned to the source nodes, based on the premise that the higher the percolation level of a source node is, the more important are the paths that originate from that node. Nodes which lie on shortest paths originating from highly percolated nodes are therefore potentially more important to the percolation. The definition of PC may also be extended to include target node weights as well. Percolation centrality calculations run in [math]\displaystyle{ O(NM) }[/math] time with an efficient implementation adopted from Brandes' fast algorithm and if the calculation needs to consider target nodes weights, the worst case time is [math]\displaystyle{ O(N^3) }[/math].

The attached weights to the percolation paths depend on the percolation levels assigned to the source nodes, based on the premise that the higher the percolation level of a source node is, the more important are the paths that originate from that node. Nodes which lie on shortest paths originating from highly percolated nodes are therefore potentially more important to the percolation. The definition of PC may also be extended to include target node weights as well. Percolation centrality calculations run in [math]\displaystyle{ O(NM) }[/math] time with an efficient implementation adopted from Brandes' fast algorithm and if the calculation needs to consider target nodes weights, the worst case time is [math]\displaystyle{ O(N^3) }[/math].

渗流路径的权重取决于分配给源节点的渗流水平,前提是源节点的渗流水平越高,源节点的路径就越重要。因此,位于源自高渗滤节点的最短路径上的节点可能对渗滤更为重要。PC 的定义也可以扩展到包括目标节点的权重。逾渗中心性计算运行在 < math > o (NM) </math > 时间,采用了 Brandes 快速算法的有效实现,如果计算需要考虑目标节点的权重,最坏情况下时间为 < math > o (n ^ 3) </math > 。


Algorithms

Calculating the betweenness and closeness centralities of all the vertices in a graph involves calculating the shortest paths between all pairs of vertices on a graph, which takes [math]\displaystyle{ \Theta(|V|^3) }[/math] time with the Floyd–Warshall algorithm, modified to not only find one but count all shortest paths between two nodes. On a sparse graph, Johnson's algorithm or Brandes' algorithm may be more efficient, both taking [math]\displaystyle{ O(|V|^2 \log |V| + |V| |E|) }[/math] time. On unweighted graphs, calculating betweenness centrality takes [math]\displaystyle{ O(|V| |E|) }[/math] time using Brandes' algorithm.模板:Sfnp

Calculating the betweenness and closeness centralities of all the vertices in a graph involves calculating the shortest paths between all pairs of vertices on a graph, which takes ^3)</math> time with the Floyd–Warshall algorithm, modified to not only find one but count all shortest paths between two nodes. On a sparse graph, Johnson's algorithm or Brandes' algorithm may be more efficient, both taking )</math> time. On unweighted graphs, calculating betweenness centrality takes )</math> time using Brandes' algorithm.

计算一个图中所有顶点的中间性和贴近度中心涉及到计算一个图中所有顶点对之间的最短路径,这需要 ^ 3) </math > 时间,使用 Floyd-Warshall 算法,修改后不仅可以找到一个,而且可以计算两个节点之间的所有最短路径。在稀疏图上,约翰逊算法或布兰德斯算法可能更有效率,两者都占用时间。在未加权图上,使用 Brandes 算法计算中间集中度需要 </math > 时间。


In calculating betweenness and closeness centralities of all vertices in a graph, it is assumed that graphs are undirected and connected with the allowance of loops and multiple edges. When specifically dealing with network graphs, often graphs are without loops or multiple edges to maintain simple relationships (where edges represent connections between two people or vertices). In this case, using Brandes' algorithm will divide final centrality scores by 2 to account for each shortest path being counted twice.模板:Sfnp

In calculating betweenness and closeness centralities of all vertices in a graph, it is assumed that graphs are undirected and connected with the allowance of loops and multiple edges. When specifically dealing with network graphs, often graphs are without loops or multiple edges to maintain simple relationships (where edges represent connections between two people or vertices). In this case, using Brandes' algorithm will divide final centrality scores by 2 to account for each shortest path being counted twice.

在计算一个图的所有顶点的中间性和贴近中心时,假定图是无向的,并且图是连通的。当专门处理网络图时,图通常没有环或多条边来维持简单的关系(其中的边表示两个人或顶点之间的联系)。在这种情况下,使用 Brandes 的算法将最终的中心性分数除以2来计算每条被重复计算的最短路径。


Another algorithm generalizes the Freeman's betweenness computed on geodesics and Newman's betweenness computed on all paths, by introducing a hyper-parameter controlling the trade-off between exploration and exploitation. The time complexity is the number of edges times the number of nodes in the graph.模板:Sfnp

Another algorithm generalizes the Freeman's betweenness computed on geodesics and Newman's betweenness computed on all paths, by introducing a hyper-parameter controlling the trade-off between exploration and exploitation. The time complexity is the number of edges times the number of nodes in the graph.

另一个算法通过引入一个超参数来控制勘探和开发之间的平衡,将大地测量学上计算的 Freeman 介数和所有路径上纽曼介数的计算结果进行了推广。时间复杂度是图中的边数乘以节点数。


The concept of centrality was extended to a group level as well.[3] Group betweenness centrality shows the proportion of geodesics connecting pairs of non-group members that pass through a group of nodes. Brandes' algorithm for computing the betweenness centrality of all vertices was modified to compute the group betweenness centrality of one group of nodes with the same asymptotic running time.[3]

The concept of centrality was extended to a group level as well. Group betweenness centrality shows the proportion of geodesics connecting pairs of non-group members that pass through a group of nodes. Brandes' algorithm for computing the betweenness centrality of all vertices was modified to compute the group betweenness centrality of one group of nodes with the same asymptotic running time.

中心性的概念也扩展到了群体层次。组间中心性反映了连接一组节点的非组成员对的测地线所占的比例。修正了布兰德斯计算所有顶点之间的中心性的算法,以计算具有相同渐近运行时间的一组节点之间的中心性。


Related concepts

Betweenness centrality is related to a network's connectivity, in so much as high betweenness vertices have the potential to disconnect graphs if removed (see cut set) .

Betweenness centrality is related to a network's connectivity, in so much as high betweenness vertices have the potential to disconnect graphs if removed (see cut set) .

中间性中心性与网络的连通性有关,在如此多的高中间性顶点中,如果移除了中断图(见割集)的可能性。


See also


Notes

  1. A. Barrat, M. Barthelemy, R. Pastor-Satorras, and A. Vespignani. The architecture of complex weighted networks. PNAS (2004) vol. 101 no. 11
  2. Piraveenan, Mahendra (2013). "Percolation Centrality: Quantifying Graph-Theoretic Impact of Nodes during Percolation in Networks". PLOS ONE. 8 (1): e53095. Bibcode:2013PLoSO...853095P. doi:10.1371/journal.pone.0053095. PMC 3551907. PMID 23349699.
  3. 3.0 3.1 Puzis, R., Yagil, D., Elovici, Y., Braha, D. (2009)Collaborative attack on Internet users’ anonymity -{zh-cn:互联网档案馆; zh-tw:網際網路檔案館; zh-hk:互聯網檔案館;}-存檔,存档日期2013-12-07., Internet Research 19(1)


References

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林顿 · 弗里曼|Freeman

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}}

}}

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}}

}}

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2010年). Networks: An Introduction

网络: 简介. Oxford, UK

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  • Dolev, Shlomi; Elovici, Yuval; Puzis, Rami (2010). "Routing betweenness centrality". J. ACM. 57 (4): 25:1–25:27. doi:10.1145/1734213.1734219.

Category:Network theory

范畴: 网络理论

Category:Graph invariants

类别: 图形不变量


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