STTR Phase I: Frequency Agile Reconfigurable WWAN/WPAN Radio Design

STTR 第一阶段：频率捷变可重配置 WWAN/WPAN 无线电设计

• 批准号: 1217530
• 负责人: Arthur Davidson
• 金额: $ 15万
• 依托单位: Carley Technologies, Inc.
• 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: 2012-07-01 至 2013-06-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1217530&HistoricalAwards=false
• 关键词: STTR; Phase; Frequency; Agile; Reconfigurable

This Small Business Technology Transfer (STTR) Phase I project will model, design, simulate, develop and transition to industrial partners the key elements of Frequency Agile Reconfigurable Radios that incorporate both medium-data-rate wireless wide area network (WWAN) radios and ultra-high-data-rate short-range wireless personal area network (WPAN) radios. Demand for wireless data will soon outstrip available RF spectrum. While limited new spectrum is available, the complexity of wireless device RF front ends is already daunting and adding more RF bands will just add more switches and more surface- acoustic-wave (SAW) filters. In the near term, the Frequency agile aspect of the proposed work will enable RF front ends that can cover the entire spectrum from 0.8GHz - 5GHz with only 3 RF front ends. This research focuses on the design of tunable LC filters coupled with adaptive cancelation of transmit tone leakage and the design of high efficiency watt-level power amplifiers. Finally, the potential for peer-to-peer ad-hoc wireless networking to provide auxiliary access to large data files of common interest will be assessed; and, a short range 60GHz transceiver front end will be designed such that the overall radio can be rapidly reconfigured to operate between 0.8-5GHz or at 60GHz.The broader impact/commercial potential of this project is that a frequency agile RF front end architecture can dramatically improve the cost and performance of wireless front ends by allowing a single transceiver and tunable RF Filter to cover any frequency band within an entire octave of frequency. An early payoff for the project will be the reduction in the number of RF switches and RF filters in the front end of wireless devices, especially cellular phones. As the number of distinct frequency bands that must be addressed by modern cell phones increases, their cost increases and their RF performance decreases because the on/off impedance ratio of available RF switches is small. The frequency agile RF front end will improve the RF performance of cellular phones due to decreased RF switch losses. This would simplify the government?s process to issue new frequency bands without considering radio complexity. The long term commercial potential for the project is its ability to dramatically reduce the data that travels over the WWAN by facilitating high data rate ad-hoc networks between mobile devices using a WPAN radio.

该小型企业技术转让（STTR）第一阶段项目将对频率捷变可重构无线电的关键要素进行建模、设计、仿真、开发并向工业合作伙伴进行过渡，这些无线电包括中等数据速率无线广域网（WWAN）无线电和超高数据速率短距离无线个域网（WPAN）无线电。 对无线数据的需求将很快超过可用的RF频谱。 虽然有限的新频谱可用，但无线设备RF前端的复杂性已经令人望而生畏，增加更多的RF频段将只会增加更多的开关和更多的表面声波（SAW）滤波器。 在短期内，拟议工作的频率捷变方面将使RF前端能够仅用3个RF前端覆盖0.8GHz - 5GHz的整个频谱。本研究的重点是可调LC滤波器的设计与传输音泄漏的自适应消除和高效率瓦级功率放大器的设计。 最后，将评估点对点特设无线网络为共同关心的大型数据文件提供辅助访问的潜力;并且，在本发明中，短程60 GHz收发器前端将被设计成使得整个无线电可以被快速重新配置为在0.8- 5 GHz或60 GHz之间工作。该项目的商业潜力在于，频率捷变RF前端架构可以通过允许单个收发器和可调谐RF滤波器覆盖整个系统内的任何频带来显著提高无线前端的成本和性能。频率的倍频程。 该项目的早期回报将是减少无线设备（特别是蜂窝电话）前端的RF开关和RF滤波器的数量。 随着现代蜂窝电话必须处理的不同频带的数量增加，它们的成本增加并且它们的RF性能降低，因为可用RF开关的开/关阻抗比很小。 频率捷变RF前端将由于降低的RF开关损耗而改善蜂窝电话的RF性能。 这将简化政府？在不考虑无线电复杂性的情况下发布新频带的过程。该项目的长期商业潜力在于，它能够通过使用WPAN无线电在移动的设备之间促进高数据速率自组织网络来显著减少在WWAN上传输的数据。