Interference and Outage in Clustered Wireless Sensor Networks with Cluster-Centric Data Collectors

Hung-Yun Hsieh, Hong-Chen Huang
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Abstract

In many wireless sensor networks, the distribution of sensor nodes involved in data transmission may be clustered as induced by the underlying geographical factor or protocol design. Instead of using the homogeneous Poisson Point Process (PPP), related work has investigated the Poisson Cluster Process (PCP) for modeling the location distribution of sensor nodes and obtaining analytical results such as the aggregate interference and outage probability for such networks. Many research endeavors, however, assume that data collectors are randomly deployed independently of the sensor nodes. While such an assumption lends itself for mathematical tractability, it is not typically how data collectors are deployed to relay data from sensor nodes to the backbone network. To address this pitfall, in this paper we consider the scenario where data collectors are deployed at the centers, or parent points, of the clusters in PCP. Since the locations of data collectors and sensor nodes are correlated, the independence assumption adopted in most related work cannot be applied. We first derive the analytical expression of the Laplace transform of the aggregate interference at each data collector and then obtain the closed-form lower bound of the transmission success probability for each sensor node to transmit data to the nearby data collector. Numerical evaluation shows that the derived lower bound matches the simulation results very well. In addition, we have also shown that placing data collectors at cluster centers, while mathematically involved for analysis, can achieve significant performance gain compared to conventional scenarios where data collectors and sensor nodes are distributed independently without any coordination.
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具有集群中心数据采集器的集群无线传感器网络中的干扰和中断
在许多无线传感器网络中,参与数据传输的传感器节点的分布可能由于潜在的地理因素或协议设计而聚类。相关工作研究了泊松聚类过程(PCP)来代替齐次泊松点过程(PPP)来建模传感器节点的位置分布,并获得了此类网络的总干扰和中断概率等分析结果。然而,许多研究工作都假设数据收集器是随机部署的,独立于传感器节点。虽然这样的假设在数学上是可追溯的,但它通常不是部署数据收集器以将数据从传感器节点中继到骨干网络的方式。为了解决这个问题,在本文中,我们考虑将数据收集器部署在PCP集群的中心或父点的场景。由于数据采集器和传感器节点的位置是相互关联的,所以大多数相关工作中采用的独立性假设不能适用。首先推导出每个数据采集器上的聚合干扰的拉普拉斯变换解析表达式,然后得到每个传感器节点向附近的数据采集器传输数据成功概率的封闭下界。数值计算表明,所得下界与仿真结果吻合较好。此外,我们还表明,将数据收集器放置在集群中心,虽然涉及数学分析,但与数据收集器和传感器节点在没有任何协调的情况下独立分布的传统场景相比,可以获得显着的性能提升。
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