Quantifying the End-to-End Delay Performance in Multihop Wireless Networks

This project uses window - based flow control and rate - based scheduling algorithms for multi - hop wireless networks with fixed - route flows performed under a general interference model with interference. The proposed algorithm not only achieves a verifiable throughput guarantee but also provides a clear upper limit to the end-to-end delay of each stream. End-to-end delay and throughput limitation is a simple closed form that explicitly quantifies the tradeoff between throughput and latency of each stream.

This is attractive for us, especially experiencing multi-hop wireless networks (or packet wireless networks, or ad hoc networks depending on name preferences). A large multihop network that fully operates autonomously and meets the communication needs of the group by providing low latency and large data rates between pairs of nodes. However, I think there are two more ubiquitous drone network drivers besides wireless multihop routing. I do not believe that both have attracted attention worthy of unmanned researchers.

Due to the diversity of the application environment of the ad hoc wireless network, different performance requirements are pursued. For example, system survivability, concealment, and confidentiality are more important in the military field, but end to end delays and packet transmission success rates are more important in wireless mobile conferencing systems. However, there are routing algorithms to solve all ad hoc network routing problems and standard protocols for ad hoc routing protocols seem unrealistic at this stage. The optimal routing algorithm should be selected according to the specific application environment. Hybrid routing algorithms combine the benefits of active and passive routing protocols with their inherent flexibility, so there is a good chance of applications.

A wireless ad hoc network, also called a wireless mesh network or a mobile ad hoc network (MANET), is a wireless network composed of wireless nodes organized in a mesh topology. Each node forwards messages on behalf of the other nodes, and each node performs routing. The ad hoc network can be "self-healing" and it will be transferred automatically, bypassing the node that was powered off. To implement an ad hoc mobile network, various network layer protocols are required, such as distance series distance vector routing, association based routing, ad hoc on - demand distance vector routing, dynamic source routing.