实现千兆赫兹大面积电子的设备、电路和系统设计

Yue Ma;Can Wu;Nicholas M. Fata;Prakhar Kumar;Sigurd Wagner;James C. Sturm;Naveen Verma
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摘要

最近的进展大大提高了大面积电子(LAE)设备的工作频率。它们与电路的集成实现了前所未有的系统级功能,面向物联网(IoT)和5G/6G的未来无线应用。这些利用了大尺寸和灵活的形状因素。在这项工作中,我们专注于将千兆赫兹(GHz)氧化锌(ZnO)薄膜晶体管(TFT)作为实现GHz LAE电路和系统的基础设备。为了进一步了解它们在新的可能频率范围内的操作和限制,我们将温度和非准静态(NQS)物理的影响纳入器件模型中。然后,我们分析了包括这些影响的基本电路块,交叉耦合电感-电容(LC)振荡器的操作。它用于代表性的LAE系统,即用于近场能量传输的13.56MHz射频识别(RFID)读取器阵列和用于远场辐射波束控制的1GHz相控阵。设备、电路和系统的共同设计对于实现灵活和米级单片集成LAE无线系统至关重要。对此,了解温度限制和NQS效应至关重要。
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Device, Circuit, and System Design for Enabling Giga-Hertz Large-Area Electronics
Recent progress has substantially increased the operating frequency of large-area electronic (LAE) devices. Their integration into circuits has enabled unprecedented system-level capabilities, toward future wireless applications for the Internet of Things (IoT) and 5G/6G. These exploit large dimensions and flexible form factors. In this work, we focus on giga-Hertz (GHz) zinc-oxide (ZnO) thin-film transistors (TFTs) as a foundational device for enabling GHz LAE circuits and systems. To further understand their operation and limits in the newly possible frequency regime, we incorporate the effects of temperature and of non-quasi-static (NQS) physics into the device models. We then analyze operation including these effects on a fundamental circuit block, the cross-coupled inductor-capacitor (LC) oscillator. It is used in representative LAE systems, namely, a 13.56-MHz radio-frequency identification (RFID) reader array for near-field energy transfer, and a 1-GHz phased array for far-field radiation beam steering. The co-design of devices, circuits, and systems is essential for achieving flexible and meter-scale monolithic-integrated LAE wireless systems. For these, understanding temperature limitations and the NQS effect is crucial.
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