Temperature- and aging-resistant inverter for robust and reliable time to digital circuit designs in a 65nm bulk CMOS process

2016 IEEE 22nd International Symposium on On-Line Testing and Robust System Design (IOLTS) Pub Date : 2016-07-04 DOI:10.1109/IOLTS.2016.7604683

Konstantin Tscherkaschin, Theodor Hillebrand, Maike Taddiken, S. Paul, D. Peters-Drolshagen

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引用次数: 2

Abstract

Inverters are one of the most basic logic blocks and exhibit a strong temperature dependency. Additionally, degradation in CMOS transistors affects the performance of circuits over time and is strongly dependent on temperature during circuit operation. In order to design robust and reliable ring oscillators and time to digital converters, both temperature dependencies have to be considered. This work introduces a circuit design for a robust and resilient inverter and an analysis on its temperature-dependent aging characteristic. The implemented inverter is driven by a common-source amplifier to achieve high robustness against temperature variation and aging effects. Based on this, circuit designs for a ring oscillator and an inverter-based delay line for a time to digital converter has been implemented. The results show that the deviation of the delay for an inverter can be minimized from 13.2% for conventional inverter design to less than 2% for the temperature-and aging-resistant design over a wide temperature range from -40° C to 150° C and a stress time of ten years.

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耐温度和耐老化逆变器，在65nm大块CMOS工艺中实现数字电路设计的鲁棒和可靠时间

逆变器是最基本的逻辑模块之一，并表现出强烈的温度依赖性。此外，CMOS晶体管的退化会随着时间的推移影响电路的性能，并且在电路工作期间强烈依赖于温度。为了设计稳健可靠的环形振荡器和时间-数字转换器，必须考虑两者的温度依赖性。本文介绍了一种鲁棒弹性逆变器的电路设计，并分析了其温度老化特性。所实现的逆变器由一个共源放大器驱动，以实现对温度变化和老化效应的高鲁棒性。在此基础上，实现了环形振荡器和基于逆变器的时数转换器延迟线的电路设计。结果表明，在-40°C至150°C的宽温度范围和10年的应力时间内，逆变器的延迟偏差可以从传统逆变器设计的13.2%降至抗温度和耐老化设计的2%以下。

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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2016 IEEE 22nd International Symposium on On-Line Testing and Robust System Design (IOLTS)

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