Digital Assistance for Nanoscale Analog Circuits

纳米级模拟电路的数字辅助

• 批准号: RGPIN-2017-06314
• 负责人: Johns, David
• 金额: $ 2.04万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=654711
• 关键词: Digital; Assistance; Nanoscale; Analog; Circuits

During the past 40 years, there has been a well-known digital revolution that has made a tremendous impact in how we live, work and play. With digital transistors shrinking as predicted by Moore's law, year over year integrated circuits and systems have continued to become lower in cost, higher in speed and lower in power dissipation for the same computation. What is less well known is that during these 40 years, there has also been an analog revolution that has been critical in improving the performance of electronic systems. These analog integrated circuits serve as the interface between the digital world and the physical world and without performance improvements in the analog circuits, the technology revolution we have seen would not have occurred. A recent review of analog circuit advancements has shown that over the past 10 years, there has been a 60 times improvement in performance. While much of this improvement (10 times) is due to transistors being smaller and faster, a large factor (6 times) has been due to creative circuit innovations which is the focus of this research grant. ******With the above in mind, a number of questions arise. Given a technology node, how close are analog circuits to the best performance achievable? Can we continue to improve analog circuits and how is this best achieved? With the tremendous improvement in digital circuits, can we make use of their decreased size/energy to aid the performance of analog circuits? These questions drive this research in the area of analog integrated circuits.******This research program is driven by the desire to enable analog circuits to be more power efficient and have higher performance when applied to numerous applications such as MEMS interface circuits, RF front-ends, high-speed signaling for serial digital communications and others. The challenge is to develop new circuits, architectures and theory that improve analog circuits and through experimental results, demonstrate the practical advantages that can be obtained.

在过去的40年里，发生了一场众所周知的数字革命，对我们的生活、工作和娱乐方式产生了巨大的影响。 随着数字晶体管如摩尔定律所预测的那样缩小，对于相同的计算，集成电路和系统年复一年地继续变得成本更低、速度更高、功耗更低。 鲜为人知的是，在这40年中，还发生了一场模拟革命，这场革命对提高电子系统的性能至关重要。 这些模拟集成电路充当数字世界和物理世界之间的接口，如果没有模拟电路的性能改进，我们所看到的技术革命就不会发生。最近对模拟电路进步的回顾表明，在过去10年中，性能提高了60倍。 虽然这种改进（10倍）大部分是由于晶体管更小更快，但很大一部分（6倍）是由于创造性的电路创新，这是这项研究资助的重点。 * 考虑到上述情况，出现了一些问题。 给定一个技术节点，模拟电路离最佳性能有多近？ 我们能否继续改进模拟电路，如何才能最好地实现这一目标？ 随着数字电路的巨大进步，我们是否可以利用它们减小的尺寸/能量来帮助模拟电路的性能？ 这些问题推动了模拟集成电路领域的研究。该研究计划的目的是使模拟电路在应用于MEMS接口电路、RF前端、串行数字通信高速信令等众多应用时具有更高的功率效率和更高的性能。挑战在于开发新的电路、架构和理论，以改进模拟电路，并通过实验结果证明可以获得的实际优势。