Miniaturized dipole antennas for ground-penetrating radar using metamaterial techniques

使用超材料技术用于探地雷达的小型偶极子天线

• 批准号: 465415-2014
• 负责人: Iyer, Ashwin
• 金额: $ 1.26万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Collaborative Research and Development Grants
• 财政年份: 2017
• 资助国家: 加拿大
• 起止时间: 2017-01-01 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=618702
• 关键词: Miniaturized; dipole; antennas; ground; penetrating

The goal of this project is to examine the feasibility of miniaturized, metamaterial-based dipole antennas in replacing the large dipole antennas in existing ground-penetrating radar (GPR) systems, while examining the effect of `metamaterialization' on pulse dispersion, antenna-current distributions, radiation pattern, bandwidth, radiation efficiency, and polarization purity. The negative-refractive-index transmission-line (NRI-TL) metamaterial has proven itself effective in miniaturizing devices whose performance relies on their size with respect to the wavelength of operation. The NRI-TL approach is ideally suited to high-frequency planar PCB TL technologies, such as microstrip, and has enabled the development of miniaturized microstrip couplers, dividers, baluns, and even miniaturized printed dipole antennas. However, these planar metamaterial technologies may be unsuitable for the high-voltage or low-frequency conditions associated with GPR systems. GPR can operate at frequencies as low as the tens of megahertz, requiring antennas that can be several metres long. Typically, these antennas are simple wire dipole antennas, and their miniaturization will necessitate the development and characterization of a suitable metamaterial topology capable of handling high-voltage signals at scaled-down frequencies. Furthermore, GPR is based on the delivery of pulses, which consist of a spectrum of frequency components. The designed metamaterial technology must also, therefore, provide broadband performance. However, the same property which enables metamaterials to provide miniaturization also introduces strong frequency dispersion, and this must be adequately characterized and compensated for by either pre- or post-processing both the transmitted and received signals according to the known frequency dispersion of the designed metamaterial. In summary, this project will investigate robust NRI-TL metamaterial topologies aimed at GPR-antenna miniaturization and will devote significant time to the theoretical investigation of pulse dispersion, recovery, and dispersion compensation.

该项目的目标是研究小型化、基于超材料的偶极子天线取代现有探地雷达（GPR）系统中大型偶极子天线的可行性，同时研究“超材料化”对脉冲色散、天线电流分布、辐射方向图、带宽、辐射效率和极化纯度的影响。负折射率传输线 (NRI-TL) 超材料已证明在小型化设备方面非常有效，这些设备的性能取决于其相对于工作波长的尺寸。 NRI-TL 方法非常适合高频平面 PCB TL 技术，例如微带线，并促进了小型化微带耦合器、分压器、巴伦甚至小型印刷偶极子天线的开发。然而，这些平面超材料技术可能不适合与探地雷达系统相关的高压或低频条件。探地雷达可以在低至数十兆赫兹的频率下工作，需要长达数米的天线。通常，这些天线是简单的线偶极子天线，它们的小型化将需要开发和表征合适的超材料拓扑，该拓扑能够在按比例缩小的频率下处理高压信号。此外，探地雷达基于脉冲传输，脉冲由一系列频率分量组成。因此，设计的超材料技术还必须提供宽带性能。然而，使超材料实现小型化的相同特性也引入了强烈的频率色散，并且必须根据设计的超材料的已知频率色散通过对发送和接收的信号进行预处理或后处理来充分表征和补偿。总之，该项目将研究旨在探地雷达天线小型化的强大 NRI-TL 超材料拓扑，并将投入大量时间进行脉冲色散、恢复和色散补偿的理论研究。