Collaborative Research: ECCS-CCSS Core: Resonant-Beam based Optical-Wireless Communication

合作研究：ECCS-CCSS核心：基于谐振光束的光无线通信

• 批准号: 2332173
• 负责人: Georgios Giannakis
• 金额: $ 20万
• 依托单位: University of Minnesota-Twin Cities
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2024
• 资助国家: 美国
• 起止时间: 2024-05-01 至 2027-04-30
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2332173&HistoricalAwards=false
• 关键词: Collaborative; Research; ECCS; CCSS; Core

This project deals with innovative optical wireless communications leveraging the resonant beam technology, where an infrared light beam is established in open air between a transmitter and a receiver in an optical cavity configuration. While progress has been made on resonant-beam based wireless charging, high-data-rate communication through the resonant-beam channel remains largely unexplored. The unique channel characteristics pose grand challenges due to the inherent nonlinearity of the lasing mechanism, and the large delay spread emerging from the oscillatory signaling operation. The project will pursue channel modelling and transceiver designs through both model-based and data-driven learning approaches and will also develop an experimental testbed for performance evaluation. Thanks to the promise of data communication through the “wireless fiber” link, and the fact that there is no interference to and from coexisting radio devices, the technology developed in this project will find emerging “killer applications” requiring high data rate and ultra-low-latency latency such as augmented reality (AR), virtual reality (VR), and Industrial Internet of Things (IIoT). Advances from this project will contribute to smart homes, smart hospitals, and smart manufacturing, and will make a profound impact to the society. This project will educate undergraduate and graduate students, improve the participation of under-represented groups, and outreach to high school students.The resonant beam channel is distinct from all channels investigated so far, including wireless infrared, visible light, radio channels including millimeter Wave and TeraHz. The transformative research is performed along three intertwined thrusts. (i) Self-driven nonlinear and time-varying Volterra series along with (multi-) kernel generalizations will be explored for nonlinear channel modelling and learning, for both the downlink and the uplink between the access point and the user equipment or sensors; (ii) Transceiver designs will start with legacy waveforms on-off-keying (OOK) and orthogonal-frequency-division-multiplexing (OFDM) for resilience to the nonlinearity and large-delay spread of the resonant beam channel. Novel end-to-end signal designs will be further investigated through artificial-intelligence (AI) tools; and (iii) Distinct optical designs with the inclusion of an adaptive optical element such as a spatial light modulator (SLM) will be pursued, which allows the system to scale to multiple users/clients, compensate for environmental disturbances, and support information transfer. Experimental data will be collected to support algorithm design, and performance validation. Investigation of this uncharted territory will leverage interdisciplinary approaches at the confluence of optical engineering, wireless communications, signal processing, and statistical learning. Novel channel models and signaling waveforms will be delivered to enrich the toolbox of wireless communications and signal processing with algorithms and the corresponding state-of-the-art communication prototypes.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

该项目涉及利用谐振光束技术的创新光无线通信，其中红外光束在光腔配置中的发射器和接收器之间的开放空气中建立。虽然在基于谐振波束的无线充电方面已经取得了进展，但通过谐振波束信道的高数据速率通信在很大程度上仍未被探索。由于激光机制的固有非线性和振荡信号操作产生的大延迟扩展，独特的信道特性提出了巨大的挑战。该项目将通过基于模型和数据驱动的学习方法进行信道建模和收发器设计，还将开发一个性能评估实验测试平台。由于通过“无线光纤”链路进行数据通信的承诺，以及共存无线电设备之间没有干扰的事实，该项目开发的技术将找到需要高数据速率和超低延迟延迟的新兴“杀手级应用”，如增强现实（AR），虚拟现实（VR）和工业物联网（IIoT）。该项目的进展将有助于智能家居，智能医院和智能制造，并将对社会产生深远的影响。该项目将教育本科生和研究生，提高代表性不足的群体的参与，并推广到高中生。谐振波束信道与迄今为止研究的所有信道不同，包括无线红外，可见光，无线电信道，包括毫米波和太赫兹。变革性的研究是沿着沿着三个相互交织的推力进行的。 (i)对于接入点和用户设备或传感器之间的下行链路和上行链路，将探索自驱动非线性和时变沃尔泰拉级数沿着（多）核概括，用于非线性信道建模和学习;（ii）收发器设计将从传统波形开关键控（OOK）和正交频分复用（OFDM）开始，以适应非线性和大的谐振束通道的延迟扩展。 将通过人工智能（AI）工具进一步研究新型端到端信号设计;（iii）将追求包含自适应光学元件（如空间光调制器（SLM））的独特光学设计，这使得系统能够扩展到多个用户/客户端，补偿环境干扰并支持信息传输。 将收集实验数据以支持算法设计和性能验证。对这一未知领域的研究将利用光学工程、无线通信、信号处理和统计学习的交叉学科方法。新的信道模型和信令波形将被交付，以丰富无线通信和信号处理的工具箱，并提供算法和相应的最先进的通信原型。该奖项反映了NSF的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。