【新书推荐】【2018.03】基于超材料表面等离子体的传输线与天线设计

本文提出了一种在各种电路元件设计中实现人工表面等离子体模式的可靠、可重复的方法。

This thesis proposes a reliable and repeatable method for implementing Spoof Surface Plasmon (SSP) modes in the design of various circuit components.

还提出了等离子体结构的第一个等效电路模型，为基于SSP的电路设计提供了一个有见地的指导。

It also presents the first equivalent circuit model for plasmonic structures, which serves as an insightful guide to designing SSP-based circuits.

如今，电子电路系统正在迅速发展，成为我们日常生活中不可缺少的一部分；然而，集成电路的紧凑性问题仍然是一个艰巨挑战。

Today, electronic circuits and systems are developing rapidly and becoming an indispensable part of our daily life; however the issue of compactness in integrated circuits remains a formidable challenge.

近年来，人工表面等离子体（SSP）模式被提出作为一种新型的高紧凑型电子电路平台。

Recently, the Spoof Surface Plasmon (SSP) modes have been proposed as a novel platform for highly compact electronic circuits.

尽管在这方面已经做了大量的研究工作，但仍然迫切需要一种等离子体电路的系统设计方法。

Despite extensive research efforts in this area, there is still an urgent need for a systematic design method for plasmonic circuits.

本文对不同的基于SSP的传输线、天线馈送网络和天线进行了设计和实验评估。

In this thesis, different SSP-based transmission lines, antenna feeding networks and antennas are designed and experimentally evaluated.

由于其高场特性的限制，SSP不受传统电路紧凑性限制，能够为未来的电子电路和电磁系统提供替代平台。

With their high field confinement, the SSPs do not suffer from the compactness limitations of traditional circuits and are capable of providing an alternative platform for the future generation of electronic circuits and electromagnetic systems.