用于远程热敏电阻线性化的高效电子数字转换器

IF 2.2 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC IEEE Sensors Letters Pub Date : 2024-10-17 DOI:10.1109/LSENS.2024.3482367
Sajeev Ramachandran;Anoop Chandrika Sreekantan;Roy Thankachan
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引用次数: 0

摘要

这封信介绍了一种专为远程热敏电阻设计的高效线性化数字接口。所提出的方法利用增强型弛豫振荡器拓扑结构,提供与感应温度成正比的直接数字输出。此外,该系统还能补偿电缆电阻,并保持传感器的恒流激励。数字转换器的设计既简单又新颖,避免了对匹配基准的需求,并将各种电路非理想状态的影响降至最低。信中介绍了接口系统的工作原理,随后进行了仿真研究。对所开发的数字转换器进行的全面硬件评估显示了良好的结果,包括低非线性度(0.41%)、高信噪比($>$67 dB)和 120 $^{\circ }$C 的测量跨度,同时不受电缆电阻的影响。该系统非常适合航空航天应用和其他需要精确热敏电阻温度测量的场合。
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Efficient Electronic Digitizer for Linearizing Remotely Located Thermistors
This letter introduces an efficient linearizing digital interface designed for remote thermistors. The proposed approach utilizes an enhanced relaxation-oscillator topology to render a direct-digital output that is directly proportional to the sensed temperature. Furthermore, the system compensates for cable resistance and maintains constant-current excitation for the sensor. The digitizer design is both simple and innovative, avoiding the need for matched references and minimizing the impact of various circuit nonidealities. The working principle of the interfacing system is established in this letter, followed by simulation studies. A thorough hardware evaluation of the developed digitizer reveals promising results, including low nonlinearity (0.41%), a high signal-to-noise ratio ( $>$ 67 dB), and a measurement span of 120 $^{\circ }$ C, all while remaining unaffected by cable resistance. This system is well-suited for aerospace applications and other scenarios, requiring accurate thermistor-based temperature measurements.
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来源期刊
IEEE Sensors Letters
IEEE Sensors Letters Engineering-Electrical and Electronic Engineering
CiteScore
3.50
自引率
7.10%
发文量
194
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