Neighbourhood watch is a concept that allows a community to distribute a complex security task in between all members. Members of the community carry out individual security tasks to contribute to the overall security of it. It reduces the workload of a particular individual while securing all members and allowing them to carry out a multitude of security tasks. Wireless sensor networks (WSNs) are composed of resource-constraint independent battery driven computers as nodes communicating wirelessly. Security in WSNs is essential. Without sufficient security, an attacker is able to eavesdrop the communication, tamper monitoring results or deny critical nodes providing their service in a way to cut off larger network parts. The resource-constraint nature of sensor nodes prevents them from running full-fledged security protocols. Instead, it is necessary to assess the most significant security threats and implement specialised protocols. A neighbourhood-watch inspired distributed security scheme for WSNs has been introduced by Langend\"orfer. Its goal is to increase the variety of attacks a WSN can fend off. A framework of such complexity has to be designed in multiple steps. Here, we introduce an approach to determine distributions of security means on large-scale static homogeneous WSNs. Therefore, we model WSNs as undirected graphs in which two nodes connected iff they are in transmission range. The framework aims to partition the graph into $n$ distinct security means resulting in the targeted distribution. The underlying problems turn out to be NP hard and we attempt to solve them using linear programs (LPs). To evaluate the computability of the LPs, we generate large numbers of random {\lambda}-precision unit disk graphs (UDGs) as representation of WSNs. For this purpose, we introduce a novel {\lambda}-precision UDG generator to model WSNs with a minimal distance in between nodes.
翻译:邻里观察是一个概念, 使社区能够在所有成员之间分配复杂的安全任务。 社区成员执行个别的安全任务, 以有助于整体安全。 它减少特定个人的工作量, 同时确保所有成员的安全, 并允许他们执行多种安全任务。 无线传感器网络( WSNs) 由资源限制的独立电池驱动的计算机组成, 以无线通讯为节点。 网络安全是不可或缺的。 没有足够安全, 攻击者能够窃听通信, 篡改监测结果, 或拒绝提供其服务的关键节点, 从而切断网络的更大部分。 传感器节点的资源限制性质使他们无法执行完整的安全协议。 相反, 有必要评估最重大的安全威胁并执行专门的协议。 由 Langend\\ orfer 引入了由资源限制独立的电池驱动的网络安全计划。 目标是增加攻击的种类, 网络安全网点可以消除。 这样的复杂度框架必须用多个步骤来设计 。 在这里, 我们引入一个方法来决定安全分配的直线性目标, 将我们使用网络的直径路路路路 。</s>