Ad hoc wireless distribution service

About: Ad hoc wireless distribution service is a research topic. Over the lifetime, 17734 publications have been published within this topic receiving 488205 citations.

Worm Epidemics in Wireless Adhoc Networks

Abstract: A dramatic increase in the number of computing devices with wireless communication capability has resulted in the emergence of a new class of computer worms which specifically target such devices. The most striking feature of these worms is that they do not require Internet connectivity for their propagation but can spread directly from device to device using a short-range radio communication technology, such as WiFi or Bluetooth. In this paper, we develop a new model for epidemic spreading of these worms and investigate their spreading in wireless ad hoc networks via extensive Monte Carlo simulations. Our studies show that the threshold behaviour and dynamics of worm epidemics in these networks are greatly affected by a combination of spatial and temporal correlations which characterize these networks, and are significantly different from the previously studied epidemics in the Internet.

Predictive route maintenance in a mobile ad hoc network

Abstract: The mobile ad hoc network includes a plurality of wireless mobile nodes and a plurality of wireless communication links connecting the nodes together. A method for operating the network includes discovering and using routes in the network, predicting route failure in the network, and performing route maintenance in the network based upon the predicted route failure.

Trust based routing mechanism for securing OSLR-based MANET

Abstract: A mobile ad hoc network (MANET) is a kind of infrastructure-less wireless network that is self-organized by mobile nodes communicating with each other freely and dynamically. MANET can be applied to many fields, such as emergency communications after disaster, intelligent transportation, and Internet of things. With the rapid development of wireless network applications, MANET will become dense and large because more and more mobile devices are required to be interconnected. The optimized link state routing (OLSR) protocol is an efficient proactive routing protocol which is very suitable for such dense and large-scale MANET. However, in both data plane and routing plane, OLSR-based MANET suffers from many serious security threats which are difficult to resist via traditional security mechanisms. In this paper, we propose a trust based routing mechanism to alleviate this issue. In this mechanism, a trust reasoning model based on fuzzy Petri net is presented to evaluate trust values of mobile nodes. In addition, to avoid malicious or compromised nodes, a trust based routing algorithm is proposed to select a path with the maximum path trust value among all possible paths. Then we extend OLSR by using the proposed trust model and trust based routing algorithm, called FPNT-OLSR. For the implementation of FPNT-OLSR, we design a trust factor collecting method and an efficient trust information propagating method, which do not generate extra control messages. Simulation results show that FPNT-OLSR is very effective in establishing secure routes. It also performs better than existing trust based OLSR protocols in terms of packet delivery ratio, average latency and overhead.

Performance Study of Node-Disjoint Multipath Routing in Vehicular Ad Hoc Networks

Abstract: Many multipath routing schemes have recently been proposed to improve the performance of wireless networks. Multipath routing is supposed to reduce the end-to-end packet delay and increase the packet delivery ratio. Therefore, it can also improve the packet delivery ratio in vehicular ad hoc networks (VANETs) when the mobility of relaying vehicles is unknown. However, in wireless networks, multiple paths are exposed to mutual interference or path coupling, which impairs efficiency. The intriguing question is whether the node-disjoint multipath routing really helps. In this paper, we examine the performance of node-disjoint multipath routing in VANETs. Through extensive simulations, we explore the effect of mutual interference on the behavior of node-disjoint paths. It is shown that whether node-disjoint paths are able to improve performance, compared with the single path, is determined by path coupling and the source-destination distance. Results show that node-disjoint multipath routing can be applied to VANETs to substantially improve performance in terms of delay and packet delivery probability only if the node-disjoint paths are properly chosen.