印刷/柔性电子器件的容差数字电路设计(特邀论文)

J. Chang, T. Ge, Tong Lin
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引用次数: 0

摘要

现代数字电路是同步逻辑的,并且在操作上没有错误,因为它们被设计成在预定义的时间段内完成操作。在某些应用中,例如在超深亚阈值中工作的MOST或在印刷TFT的柔性电子器件中,数字电路的后续操作容易出错。这是因为晶体管延迟的变化是非常高的,随后预定义的时间周期是难以确定的。在印刷TFT的情况下,其衬底是柔性的,因此可能弯曲,延迟可能是棘手的,部分原因是弯曲的轮廓可能不知道。在本文中,我们将讨论超深亚阈值和印刷tft在其变化方面的共性。我们描述了深奥的异步逻辑准延迟不敏感(QDI)信令协议的应用,以设计天生适应难以处理的延迟特性的数字电路,即,尽管难以处理的变化,但无错误操作。为了减少QDI的硬件、电源和时序开销,我们将提出我们提议的修改后的信令协议,命名为Pseudo-QDI和我们提议的预充电静态逻辑设计风格。
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Variation-Tolerant Digital Circuit Design for Printed/Flexible Electronics (Invited Paper)
Contemporary digital circuits are synchronous-logic and are operationally error-free because they are designed to complete their operation within a predefined time period. In some applications, such as the MOST operating in ultra-deep subthreshold or in flexible electronics where the TFT is printed, the ensuing operation of digital circuits is prone to error. This is because the variations of the delay of the transistor are very high and the ensuing predefined time period is difficult to ascertain. In the case of the printed TFT where its substrate is flexible and hence possibly bent, the delay is possibly intractable, in part because the profile of the bending may not be known. In this paper, we will discuss the commonality between ultra-deep subthreshold and printed TFTs in terms of their variations. We describe the application of the esoteric asynchronous-logic Quasi-Delay-Insensitive (QDI) signaling protocol to design digital circuits that innately accommodate intractable delay characteristics, i.e., error-free operation despite intractable variations. To mitigate the hardware, power and timing overheads of QDI, we will present our proposed modified signaling protocol named Pseudo-QDI and our proposed Pre-Charged-Static-Logic design style.
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