ECCS-EPSRC: Towards Quantum-assisted Reconfigurable Indoor Wireless Environments

ECCS-EPSRC：迈向量子辅助可重构室内无线环境

• 批准号: EP/X038491/1
• 负责人: Gabriele Gradoni
• 金额: $ 45.53万
• 依托单位: University of Surrey
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2023
• 资助国家: 英国
• 起止时间: 2023 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=EP%2FX038491%2F1
• 关键词: ECCS; EPSRC; Towards; Quantum; assisted

Indoor scenario has emerged as one of the most congested, contested, and competitive wireless environments. With the need of resilient Internet of Everything (IoE) and Fourth Industrial Revolution (Industry 4.0) infrastructures, we expect to connect thousands of devices within a confined indoor environment, interfering to each other and contending for limited electromagnetic spectrum. While the growing demand for data traffic meets confined space and congested spectrum, it creates a clear andpresent technical challenge, and opportunities for innovation. The research objective of this proposal is to investigate new fundamental communication models and schemes, which dynamically program and customize indoor wireless propagation environments for enhanced wireless communication. This objective is attained by integrating the physics of wave-chaotic dynamics, the mathematics of random matrix theory, the engineering of reconfigurable electromagnetic surfaces, and the computing power of adiabatic quantum annealer. The proposed work consists of three components: (1) rigorous mathematical model for the statistical analysis of wave physics in complex confined indoor environment; (2) the configuration and control of wave chaos using reconfigurable intelligent surfaces; (3) Quantum-enabled, ultra-fast large-scale optimization of reconfigurable intelligent surface configuration.

室内场景已经成为最拥挤、竞争最激烈的无线环境之一。随着弹性万物互联（IoE）和第四次工业革命（工业4.0）基础设施的需求，我们预计将在受限的室内环境中连接数千台设备，相互干扰并争夺有限的电磁频谱。虽然不断增长的数据流量需求满足了有限的空间和拥挤的频谱，但它带来了明确而现实的技术挑战，也带来了创新机会。本文的研究目标是探索新的基本通信模型和方案，动态规划和定制室内无线传播环境，以增强无线通信。这一目标是通过整合波混沌动力学的物理、随机矩阵理论的数学、可重构电磁表面的工程和绝热量子退火炉的计算能力来实现的。本文主要由三个部分组成：(1)建立复杂密闭室内环境下波动物理统计分析的严格数学模型；(2)基于可重构智能曲面的波混沌配置与控制；(3)可重构智能表面配置的量子超快速大规模优化。