采用180nm CMOS工艺，实现了分辨率0.5°C、线性误差0.34%的片上温度传感器

IF 2.2 3区工程技术 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Integration-The Vlsi Journal Pub Date : 2025-01-24 DOI:10.1016/j.vlsi.2025.102362

Chua-Chin Wang , Pradyumna Vellanki , Shih-Heng Luo , Ralph Gerard B. Sangalang

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引用次数: 0

摘要

本研究展示了一种最大线性误差小于0.4%和0.5°C分辨率的片上温度传感器。该设计包括电流-频率转换器（CFC），互补（CTAT）和比例（PTAT）到绝对温度电流发生器电路。最重要的是，所提出的传感器具有这两个电流的比值，以提高线性度和高分辨率。该传感器采用180nm CMOS工艺实现。核心区面积0.196 mm2。测量结果表明，PTAT/CTAT比的最大线性误差为0.3484%。温度探测器的最大输出频率为4.817 MHz，最高功耗为20.13 mW。它被证明可用于-40°C ~ 100°C的温度检测范围，分辨率为0.5°C。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

An on-chip temperature sensor with 0.5 °C resolution and 0.34% linearity error using 180-nm CMOS process

查看原文本刊更多论文

An on-chip temperature sensor with 0.5 °C resolution and 0.34% linearity error using 180-nm CMOS process

This investigation demonstrates an on-chip temperature sensor with a maximum linear error less than 0.4% and 0.5 °C resolution. The design comprises Current-to-Frequency Converters (CFC), complementary (CTAT), and proportional (PTAT) to absolute temperature current generator circuits. Most important of all, the proposed sensor is featured with the ratio of these two currents to enhance the linearity and high resolution. The proposed sensor was realized using a 180-nm CMOS process. The core area is 0.196 mm

^{2}

. The measurement results show 0.3484% maximum linearity error for the PTAT/CTAT ratio. The maximum output frequency of the temperature detector is 4.817 MHz, with the highest power consumption of 20.13 mW. It was proved to be used in a –40 °C

\sim

100 °C temperature detection range with 0.5 °C resolution.

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来源期刊

Integration-The Vlsi Journal 工程技术-工程：电子与电气

CiteScore

3.80

自引率

5.30%

发文量

107

审稿时长

6 months

期刊介绍： Integration''s aim is to cover every aspect of the VLSI area, with an emphasis on cross-fertilization between various fields of science, and the design, verification, test and applications of integrated circuits and systems, as well as closely related topics in process and device technologies. Individual issues will feature peer-reviewed tutorials and articles as well as reviews of recent publications. The intended coverage of the journal can be assessed by examining the following (non-exclusive) list of topics: Specification methods and languages; Analog/Digital Integrated Circuits and Systems; VLSI architectures; Algorithms, methods and tools for modeling, simulation, synthesis and verification of integrated circuits and systems of any complexity; Embedded systems; High-level synthesis for VLSI systems; Logic synthesis and finite automata; Testing, design-for-test and test generation algorithms; Physical design; Formal verification; Algorithms implemented in VLSI systems; Systems engineering; Heterogeneous systems.