CIF: Medium: Collaborative Research: Interference-Aware Cooperation via Structured Codes: Creating an Empirical Cycle

CIF：媒介：协作研究：通过结构化代码进行干扰感知合作：创建经验循环

• 批准号: 1302600
• 负责人: Bobak Nazer
• 金额: $ 37.67万
• 依托单位: Trustees of Boston University
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-08-01 至 2017-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1302600&HistoricalAwards=false
• 关键词: CIF; Medium; Collaborative; Research; Interference

The classical approach to wireless communication is to isolate communication links by maximizing signal strength and minimizing interference between users. This simple philosophy is supported by a rich theoretical foundation which has inspired powerful coding techniques and protocols that lie at the heart of modern wireless systems. However, these systems have recently become victims of their own success as the rising density and data requirements of wireless devices have led to a surge in interference. Fortunately, an emerging body of work indicates that the phenomenon of interference may in fact represent an untapped opportunity for increasing the spectral and energy efficiency of next-generation wireless systems. Although many interference-aware communication strategies have been proposed in the literature, the promised gains have been mostly limited to the theoretical realm. The objective of this project is to create practical interference-aware wireless protocols that can operate near the performance predicted by theoretical bounds in terms of throughput, energy efficiency, and reliability. The project is organized into three complementary thrusts that encompass theory, algorithms, and practice. The first thrust investigates lattice-based constellations and low-complexity codes for the compute-and-forward strategy, which enables receivers to decode linear combinations of transmitted codewords. Compute-and-forward can in turn be used as a building block for realizing interference-aware protocols such as physical-layer network coding and multiple-user MIMO (multi-input-uulti-output) systems. The second thrust aims to implement these protocols on a three-node WARP (Wireless Open-Access Research Platform) testbed. A series of carefully designed experiments will be used to compare the performance of interference-aware strategies while accounting for overhead costs. The third thrust leverages the data collected from these experiments to revise channel models to capture key features that impact the performance of interference-aware strategies such as asynchronism and channel fluctuations. These models will be used to revisit the theoretical foundations of interference-aware strategies and tailor them to the channels encountered in practice. This project features several outreach efforts including undergraduate research experiences connected to the WARP testbed and a public repository of training modules and videos.

无线通信的经典方法是通过最大化信号强度和最小化用户之间的干扰来隔离通信链路。这一简单的理念得到了丰富的理论基础的支持，这些理论基础激发了现代无线系统核心的强大编码技术和协议。然而，这些系统最近成为其自身成功的受害者，因为无线设备的密度和数据需求的上升导致干扰激增。幸运的是，新出现的大量工作表明，干扰现象实际上可能代表了提高下一代无线系统频谱和能源效率的未开发机会。虽然许多干扰感知的通信策略已被提出在文献中，承诺的收益大多局限于理论领域。该项目的目标是创建实用的干扰感知无线协议，这些协议可以在吞吐量、能效和可靠性方面接近理论界限预测的性能运行。该项目被组织成三个互补的推力，包括理论，算法和实践。第一个推力调查基于格的星座和低复杂度的代码的计算和转发策略，这使得接收器能够解码发送码字的线性组合。计算和转发又可以用作实现干扰感知协议的构建块，例如物理层网络编码和多用户MIMO（多输入多输出）系统。第二个目标是在三节点WARP（无线开放访问研究平台）测试平台上实现这些协议。将使用一系列精心设计的实验来比较干扰感知策略的性能，同时考虑管理费用。第三个推力利用从这些实验中收集的数据来修改信道模型，以捕获影响干扰感知策略性能的关键特征，例如干扰和信道波动。这些模型将用于重新审视干扰感知策略的理论基础，并将其调整为实践中遇到的渠道。该项目的特点是几个外展工作，包括连接到WARP测试平台和培训模块和视频的公共存储库的本科生研究经验。