On k-connectivity for a geometric random graph
Random Structures & Algorithms
Wireless Communications: Principles and Practice
Wireless Communications: Principles and Practice
The number of neighbors needed for connectivity of wireless networks
Wireless Networks
Extremal Properties of Three-Dimensional Sensor Networks with Applications
IEEE Transactions on Mobile Computing
Impact of interferences on connectivity in ad hoc networks
IEEE/ACM Transactions on Networking (TON)
Connectivity in wireless ad-hoc networks with a log-normal radio model
Mobile Networks and Applications
Wireless sensor network localization techniques
Computer Networks: The International Journal of Computer and Telecommunications Networking
IEEE Transactions on Computers
Asymptotic connectivity in wireless ad hoc networks using directional antennas
IEEE/ACM Transactions on Networking (TON)
Stochastic geometry and random graphs for the analysis and design of wireless networks
IEEE Journal on Selected Areas in Communications - Special issue on stochastic geometry and random graphs for the analysis and designof wireless networks
Asymptotic connectivity properties of cooperative wireless ad hoc networks
IEEE Journal on Selected Areas in Communications - Special issue on stochastic geometry and random graphs for the analysis and designof wireless networks
The Impact of Channel Randomness on Coverage and Connectivity of Ad Hoc and Sensor Networks
IEEE Transactions on Wireless Communications
Closing the Gap in the Capacity of Wireless Networks Via Percolation Theory
IEEE Transactions on Information Theory
Towards a better understanding of large-scale network models
IEEE/ACM Transactions on Networking (TON)
Towards a better understanding of large-scale network models
IEEE/ACM Transactions on Networking (TON)
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Connectivity and capacity are two fundamental properties of wireless multihop networks. The scalability of these properties has been a primary concern for which asymptotic analysis is a useful tool. Three related but logically distinct network models are often considered in asymptotic analyses, viz. the dense network model, the extended network model, and the infinite network model, which consider respectively a network deployed in a fixed finite area with a sufficiently large node density, a network deployed in a sufficiently large area with a fixed node density, and a network deployed in R2 with a sufficiently large node density. The infinite network model originated from continuum percolation theory and asymptotic results obtained from the infinite network model have often been applied to the dense and extended networks. In this paper, through two case studies related to network connectivity on the expected number of isolated nodes and on the vanishing of components of finite order k 1 respectively, we demonstrate some subtle but important differences between the infinite network model and the dense and extended network models. Therefore, extra scrutiny has to be used in order for the results obtained from the infinite network model to be applicable to the dense and extended network models. Asymptotic results are also obtained on the expected number of isolated nodes, the vanishingly small impact of the boundary effect on the number of isolated nodes, and the vanishing of components of finite order k 1 in the dense and extended network models using a generic random connection model.