WiFiUS: Collaborative Research: Future Small-Cell Networks Using Reconfigurable Antennas

WiFiUS：合作研究：使用可重新配置天线的未来小蜂窝网络

• 批准号: 1457310
• 负责人: Alexander Wyglinski
• 金额: $ 9.02万
• 依托单位: Worcester Polytechnic Institute
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2015
• 资助国家: 美国
• 起止时间: 2015-02-01 至 2017-01-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1457310&HistoricalAwards=false
• 关键词: WiFiUS; Collaborative; Research; Future; Small

The future proliferation of wireless systems and services is dependent on the design of flexible radio architectures that can adapt to the rapidly changing wireless environment. Since usable spectrum is limited, and modulation and coding techniques are approaching their Shannon capacity limitation, improving capacity through increased spectrum reuse and interference mitigation has become a high priority in future cellular networks. Industry leaders have focused on a multi-tiered heterogeneous network structure, where small-cell (e.g., pico-cell, femto-cell) base stations are deployed to meet capacity demand. Among the technical challenges making full-scale deployment of small-cell base stations possible, interference management still looms the largest. This project focuses on providing wireless systems with the available hardware and algorithmic tools to make intelligent decisions about antenna configuration for small-cell base stations to mitigate interference and improve network capacity and coexistence in a heterogeneous network environment.This project is composed of three main research thrusts: i.) Algorithm and System Design; ii.) Antenna and Transceiver Design; and iii.) Testbed Implementation. The first focus is on the mathematical modeling and overall system design of small-cell networks making use of reconfigurable antennas. A vital component of this overall system design is the development of efficient and effective analytical tools and algorithms for downlink transmission, focusing on directional network design, algorithms for directionality selection, and base station user association. The second thrust includes the development of practical reconfigurable antennas and transceiver processing techniques for small-cell base stations. The project team is adapting reconfigurable metamaterial and alford loop antenna designs to provide new, compact reconfigurable antenna architectures with both beam steering and variable beam width capabilities. Using these new antenna technologies this research enhances direction of arrival and digital pre-distortion techniques for enhanced small-cell uplink and downlink. The cornerstone of this research is the design of a fully implemented, programmable across-the-stack SDR platform with integrated reconfigurable antennas. This project makes use of open-source technologies and will result in the deployment of a fully functional cellular backbone system, consisting of both macro-cell and small-cell base stations.This project leverages collaboration between Drexel University and WPI, along with a strong international collaboration with the University of Oulu, VTT Technical Research Centre and Tampere University of Technology. This ongoing collaboration with Finnish institutions continues to provide novel international research experiences for undergraduate and graduate students as well as pilot testing for dissemination of the developed testbed.

未来无线系统和服务的普及取决于能够适应快速变化的无线环境的灵活无线电架构的设计。由于可用频谱有限，并且调制和编码技术正在接近其香农容量限制，因此通过增加频谱重用和干扰抑制来提高容量已成为未来蜂窝网络的重中之重。行业领导者重点关注多层异构网络结构，其中部署小型蜂窝（例如微微蜂窝、毫微微蜂窝）基站以满足容量需求。在实现小蜂窝基站全面部署的技术挑战中，干扰管理仍然是最大的挑战。该项目的重点是为无线系统提供可用的硬件和算法工具，以便对小蜂窝基站的天线配置做出智能决策，以减轻干扰并提高网络容量和异构网络环境中的共存。该项目由三个主要研究方向组成：i.）算法和系统设计； ii.) 天线和收发器设计； iii.) 测试平台实施。第一个重点是利用可重构天线的小型蜂窝网络的数学建模和总体系统设计。整个系统设计的一个重要组成部分是开发下行链路传输的高效分析工具和算法，重点关注定向网络设计、方向性选择算法和基站用户关联。第二个推动力包括开发用于小型基站的实用可重构天线和收发器处理技术。该项目团队正在采用可重构超材料和阿尔福德环形天线设计，以提供具有波束控制和可变波束宽度功能的新型紧凑型可重构天线架构。利用这些新的天线技术，本研究增强了到达方向和数字预失真技术，以增强小型蜂窝上行链路和下行链路。这项研究的基石是设计一个完全实现的、具有集成可重构天线的可编程跨堆栈 SDR 平台。该项目利用开源技术，将部署一个功能齐全的蜂窝骨干系统，包括宏蜂窝和小蜂窝基站。该项目利用了德雷克塞尔大学和 WPI 之间的合作，以及与奥卢大学、VTT 技术研究中心和坦佩雷理工大学的强有力的国际合作。与芬兰机构的持续合作继续为本科生和研究生提供新颖的国际研究经验，并为传播所开发的测试平台进行试点测试。