Process-Scalable and Loew-Power Amplifiers: Progress and prospects in dynamic amplifier research

IEEE Solid-State Circuits Magazine Pub Date : 2024-08-23 DOI:10.1109/MSSC.2024.3416094

Sein Oh;Minkyu Je

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Abstract

Amplifiers are critical components in many applications. They simply perform signal amplification, but real-world implementation must consider several challenges, such as finite BW, signal distortion, noise, stability, and so on. Solutions to these problems typically involve circuit techniques that lead to high power consumption. Therefore, numerous studies have been conducted to break the tradeoff between performance and power. Among the most promising candidates is the current-reuse structure [1] , [2] , [3] , [4] , [5] , [6] . Such amplifiers have continuously improved their power efficiency factor (PEF) performance year by year. However, there are essential limitations to consider. First, the supply voltage significantly decreases as the process node advances. This process scaling not only makes it challenging for amplifiers to achieve high gain but also significantly degrades linearity. Second, conventional amplifiers, meaning continuous-time (CT) amplifiers, operate with a static current. While better PEFs of CT amplifiers improve overall performance envelopes in many CT-domain applications, they exhibit clear limitations in discrete-time (DT)-domain or mixed-signal applications.

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过程可变和 Loew 功率放大器：动态放大器研究的进展与前景

放大器是许多应用中的关键元件。它们只需进行信号放大，但在实际应用中必须考虑几个挑战，如有限的 BW、信号失真、噪声、稳定性等。这些问题的解决方案通常涉及导致高功耗的电路技术。因此，为了打破性能与功耗之间的平衡，人们进行了大量研究。其中最有前途的候选方案是电流重复使用结构 [1]、[2]、[3]、[4]、[5]、[6]。这类放大器的功率效率因子（PEF）性能逐年提高。然而，也有一些基本限制需要考虑。首先，随着工艺节点的发展，电源电压会明显降低。这种工艺缩放不仅给放大器实现高增益带来了挑战，而且还大大降低了线性度。其次，传统放大器，即连续时间（CT）放大器，以静态电流工作。虽然 CT 放大器更好的 PEF 改善了许多 CT 域应用的整体性能范围，但在离散时间 (DT) 域或混合信号应用中却表现出明显的局限性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Solid-State Circuits Magazine

CiteScore

2.50

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0.00%

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