NeTS: Small: Collaborative Research: OSTARA: An Optically-based Simultaneous Transmit and Receive Architecture for Enhancing Wireless Communications

NeTS：小型：协作研究：OSTARA：用于增强无线通信的基于光学的同步发送和接收架构

• 批准号: 1217435
• 负责人: Paul Prucnal
• 金额: $ 25万
• 依托单位: Princeton University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-09-01 至 2015-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1217435&HistoricalAwards=false
• 关键词: NeTS; Small; Collaborative; Research; OSTARA

Improving the usage of communication spectrum resources is critical to future wireless systems. The OSTARA project focuses on the development of RF photonic techniques that support the ability to simultaneously transmit and receive in wireless devices. The effort involves a mix of theoretical development (specifically investigating potential improvements in capacity), as well as systems validation efforts involving building an opto-cancellation circuit capable of cancelling out co-site interference associated with simultaneous transmission and reception. . Specifically, the theoretical component of the effort will involve using ray-tracing to understand the role of cancelation of multipath components on communication rate, as well as an investigation into the impact of idealized cancellation on network capacity using graph coloring. The systems component of the effort will involve developing photonic circuits that subtract off the transmitted signal from the receiver chain, as well as potential multipath images of the transmitted signal. Validation will involve field testing the opto-canceller by setting up test scenarios on the ORBIT testbed at WINLAB.Broader Impact: The proposed research will improve the spectrum utilization of future wireless systems, an issue of critical national importance. Additionally, the project will educate students and post-doctoral fellows in the inter-disciplinary area of RF-photonics as applied to advanced radio systems.

提高通信频谱资源的利用率对于未来的无线系统至关重要。OSTARA项目的重点是开发RF光子技术，支持在无线设备中同时发送和接收的能力。这项工作涉及理论开发（特别是研究容量的潜在改进），以及系统验证工作，包括建立一个光消除电路，能够消除与同时发送和接收相关的共址干扰。.具体来说，理论部分的努力将涉及使用射线跟踪来了解消除多径分量对通信速率的作用，以及调查理想化的消除对网络容量的影响，使用图形着色。这项工作的系统部分将涉及开发光子电路，从接收器链中减去传输信号，以及传输信号的潜在多径图像。验证将涉及通过在WINLAB的ORBIT测试平台上设置测试场景来对光电抵消器进行现场测试。 拟议的研究将提高未来无线系统的频谱利用率，这是一个至关重要的国家问题。 此外，该项目将教育学生和博士后研究员在射频光子学的跨学科领域应用于先进的无线电系统。