CIF:Small:Physical Layer Optimization for Cognitive Sensor Networks

CIF：小：认知传感器网络的物理层优化

• 批准号: 0916073
• 负责人: Arnold Swindlehurst
• 金额: $ 30.59万
• 依托单位: University of California-Irvine
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2009
• 资助国家: 美国
• 起止时间: 2009-07-01 至 2013-06-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0916073&HistoricalAwards=false
• 关键词: CIF; Small; Physical; Layer; Optimization

Physical Layer Optimization for Cognitive Sensor NetworksThe cognitive radio concept has been a revolutionary development in wireless communications systems. Cognitive, software-defined radios are able to adjust link and network resources in order to optimize communications performance. However, high rate, robust communications is often just one of many possible network objectives. For example, in sensing applications, the goal is to maximize coverage, detect important events with high probability, and track objects of interest with high accuracy. These goals are often at odds with those for optimum communications; improved coverage requires more widely dispersed sensors, complicating network connectivity. High resolution sensing requires more bits of information, which in turn place a strain on network throughput. Power devoted to routing or packet forwarding reduces a sensors lifetime. Clearly, a different paradigm is needed when sensing performance is the critical factor, or perhaps most interestingly, when both communications and sensing performance must be considered in tandem. This research effort introduces Cognitive Sensing as a concept dual to that of cognitive communications, and investigates the competing objectives of sensing and communications networks. A cognitive sensor would adaptively adjust its operating parameters in response to the environment it finds itself in so as to optimize sensing performance, or perhaps a dual performance metric that includes both sensing and communications functions. Parameters relevant to sensing performance could include sensor position, speed and heading, antenna beampattern and polarization, transmit waveform type and bandwidth, imaging camera zoom, orientation, resolution, pointing angle, etc. The question of how to allocate such sensor resources is central to this effort.

认知传感器网络的物理层优化认知无线电概念是无线通信系统的革命性发展。 认知软件定义无线电能够调整链路和网络资源，以优化通信性能。然而，高速率、稳健的通信通常只是众多可能的网络目标之一。例如，在传感应用中，目标是最大化覆盖范围、以高概率检测重要事件并以高精度跟踪感兴趣的对象。 这些目标常常与最佳沟通的目标不一致；扩大覆盖范围需要更广泛分布的传感器，从而使网络连接变得复杂。高分辨率传感需要更多位的信息，这反过来又对网络吞吐量造成压力。用于路由或数据包转发的功率会缩短传感器的使用寿命。 显然，当传感性能是关键因素时，或者最有趣的是，当必须同时考虑通信和传感性能时，需要不同的范例。 这项研究工作将认知感知作为认知通信的双重概念引入，并研究了感知和通信网络的竞争目标。 认知传感器将根据其所处的环境自适应地调整其操作参数，以优化传感性能，或者可能是包括传感和通信功能的双重性能指标。与传感性能相关的参数可能包括传感器位置、速度和航向、天线波束方向图和极化、发射波形类型和带宽、成像相机变焦、方向、分辨率、指向角度等。如何分配此类传感器资源的问题至关重要。这个努力。