Millimeter-wave and Terahertz Real-Time and Space Processing based on Metamaterial Technology

基于超材料技术的毫米波和太赫兹实时和空间处理

• 批准号: RGPIN-2015-06095
• 负责人: Caloz, Christophe
• 金额: $ 4.23万
• 依托单位: École Polytechnique de Montréal
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=613941
• 关键词: Millimeter; wave; Terahertz; Real; Time

Today’s exploding demand for faster, more reliable, and ubiquitous radio systems in communications, instrumentation, radar, imaging and sensors poses unprecedented challenges in microwave (mw), millimeter-wave (mmw) and terahertz (THz) engineering. Recently, the predominant trend has been to place increasing emphasis on digital signal processing (DSP). However, while offering device compactness and processing flexibility, DSP suffers from intrinsic drawbacks, such as limited speed, high-cost analog-digital conversion, high power consumption, and poor performance at high frequencies, leading to serious technological bottlenecks. For instance, in wireless communications, a 1,000-fold increase in data capacity demand over the 5 next years has been predicted, and it is widely recognized by industrial experts that current technologies will be largely insufficient to meet such requirements! Therefore, novel paradigms and disruptive technological solutions are urgently needed. The proposed research program proposes a radically different approach to address the aforementioned challenges by leveraging metamaterial technology. Inspired from ultrafast optics, it will develop mmw and THz real-time analog signal processing, consisting in manipulating high-frequency signals in their pristine analog form and in real time to realize specific processing operations, as an alternative to DSP-based processing. This is essentially temporal dispersion engineering, where linear components such as metamaterial-based “phasers” (term borrowed from acoustics) and nonlinear components called “companders” (portmanteau for compressors and expandors) will be elaborated to control the phase and group delay of mww/THz systems in unprecedented fashions. As electromagnetic waves propagate both in time and space, spatial dispersion engineering appears to be a natural processing complement to its temporal counterpart. The proposed program will thus develop, this time inspired from optical analog signal processing, novel types of mmw and THz antennas and surfennas (metasurfaces operated in the monochromatic regime), such as for instance vortex wave antennas and generalized refraction surfennas. Finally, the program will investigate devices operating simultaneously as temporal and spatial processors, namely “phasennas,” “compandenas” and “surfphasennas.” The proposed time/space/spacetime processors will lead to a great diversity of applications, such as real-time/space Fourier transformers and spectrogram analyzers, real-time convolvers/correlators, nonreciprocal devices, dispersion encoders, vortex multiplexers, maxwellian spatial systems, and space-time cloaks, with application areas as various as communications, wireless energy transfer, sensing/imaging, instrumentation, security/defense, biomedicine, nanoelectromagnetics and astronomy.

当今通信、仪器仪表、雷达、成像和传感器对更快、更可靠和无处不在的无线电系统的需求呈爆炸式增长，这对微波（mw）、毫米波（mmw）和太赫兹（THz）工程提出了前所未有的挑战。近年来，数字信号处理（DSP）的发展趋势越来越突出。然而，DSP在提供器件紧凑性和处理灵活性的同时，也存在固有的缺陷，如速度有限、模数转换成本高、功耗高、高频性能差等，导致了严重的技术瓶颈。例如，在无线通信中，已经预测在未来5年内数据容量需求将增长1,000倍，并且工业专家广泛认识到，当前技术将在很大程度上不足以满足这样的需求！因此，迫切需要新的范式和颠覆性的技术解决方案。 拟议的研究计划提出了一种完全不同的方法，通过利用超材料技术来解决上述挑战。受超快光学的启发，它将开发毫米波和太赫兹实时模拟信号处理，包括以原始模拟形式和真实的时间操纵高频信号，以实现特定的处理操作，作为基于DSP的处理的替代方案。这本质上是时间色散工程，其中线性组件，如基于超材料的“相位器”（从声学中借用的术语）和称为“压扩器”（压缩器和扩展器的合成词）的非线性组件将被精心设计，以前所未有的方式控制mww/THz系统的相位和群延迟。 由于电磁波在时间和空间中传播，空间色散工程似乎是其时间对应物的自然处理补充。因此，拟议的计划将开发，这一次的灵感来自光学模拟信号处理，新型的毫米波和太赫兹天线和surfennas（在单色制度下操作的超表面），例如涡旋波天线和广义折射surfennas。最后，该计划将研究同时作为时间和空间处理器运行的设备，即“phasennas”，“compandenas”和“surfphasennas”。 提出的时间/空间/时空处理器将导致各种各样的应用，例如实时/空间傅立叶变换器和频谱分析器、实时卷积器/卷积器、非互易设备、色散编码器、涡旋复用器、麦克斯韦空间系统和时空斗篷，其应用领域包括通信、无线能量传输、传感/成像、仪器仪表、安全/国防、生物医学、纳米电磁学和天文学。