Unmanned Aerial Vehicles (UAVs) have emerged as adequate platforms to carry communications nodes, including Wi-Fi Access Points and cellular Base Stations. This has led to the concept of flying networks composed of UAVs as a flexible and agile solution to provide on-demand wireless connectivity anytime, anywhere. However, state of the art works have been focused on optimizing the placement of the access network providing connectivity to ground users, overlooking the backhaul network design. In order to improve the overall Quality of Service (QoS) offered to ground users, the placement of Flying Gateways (FGWs) and the size of the queues configured in the UAVs need to be carefully defined to meet strict performance requirements. The main contribution of this article is a traffic-aware gateway placement and queue management (GPQM) algorithm for flying networks. GPQM takes advantage of knowing in advance the positions of the UAVs and their traffic demand to determine the FGW position and the queue size of the UAVs, in order to maximize the aggregate throughput and provide stochastic delay guarantees. GPQM is evaluated by means of ns-3 simulations, considering a realistic wireless channel model. The results demonstrate significant gains in the QoS offered when GPQM is used.
翻译:无人驾驶航空飞行器(无人驾驶飞行器)已成为传送通信节点(包括无线接入点和蜂窝基地站)的适当平台,由此产生了由无人驾驶飞行器组成的飞行网络的概念,作为灵活和灵活的解决办法,随时随地随时随地提供即时无线连接,但最新工作的重点是优化连接地面用户的接入网络的位置,忽视回路网络设计;为了提高向地面用户提供的服务的总体质量(QOS),需要仔细确定由无人驾驶飞行器组成的飞行网关(FGW)的位置和配置在无人驾驶飞行器中的队列的大小,以满足严格的性能要求;这一文章的主要贡献是飞行网络的交通安全网关位置和排队管理(GPQM)算法。 GPQM利用预先了解UA公司的位置及其交通需求,以确定向地面用户提供的FGW公司的位置和排队规模,以便尽可能扩大总压,并提供随机的延迟模型。