An Integrated Fully Differential Current Amplifier With Frequency Compensation for Inductive Sensor Excitation

IF 2.4 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE open journal of circuits and systems Pub Date : 2025-02-27 DOI:10.1109/OJCAS.2025.3546464

Maximilian Scherzer;Mario Auer

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Abstract

In this article an integrated fully differential current amplifier is presented. It was designed for inductive sensor excitation, in this case for a fluxgate sensor, however the concept is applicable wherever a low noise and precise current is required. A brief review of some of the basic elements of the circuit is given, followed by the development of a model that takes into account output impedance limitations due to mismatch and stability criteria, an essential consideration in the design of a stable current amplifier for inductive loads. Based on the proposed model, the design and implementation of the current amplifier is outlined, identifying potential difficulties for on-chip integration. The final design was then fabricated using a standard 180nm CMOS technology. Measurement results show that the circuit draws only 2.8 mA from a 3.3V supply voltage and occupies a total area of 0.64 mm2. Special efforts were made to accurately evaluate the output impedance, whereby a value of 436k

$\Omega $

was recorded. In addition, the current amplifier achieves an output-referred noise current of 2.5

$\text {nA}/\sqrt {\text {Hz}}$

, resulting in a measured signal-to-noise ratio of more than 105.2 dB for a bandwidth of 512 Hz at an output current of 9

$\text {mA}_{\text {p-p}}$

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带频率补偿的集成式电感传感器激励全差分电流放大器

本文介绍了一种集成式全差动电流放大器。它是为电感传感器激励而设计的，在这种情况下是磁通门传感器，但是这个概念适用于任何需要低噪声和精确电流的地方。简要回顾了电路的一些基本元件，然后开发了一个模型，该模型考虑了由于失配和稳定性标准而导致的输出阻抗限制，这是设计用于电感负载的稳定电流放大器的基本考虑因素。基于所提出的模型，概述了电流放大器的设计和实现，确定了片上集成的潜在困难。然后使用标准的180nm CMOS技术制造最终设计。测量结果表明，该电路在3.3V电源电压下的功耗仅为2.8 mA，总面积为0.64 mm2。我们做了特别的努力来准确地评估输出阻抗，因此记录了436k $\Omega $的值。此外，电流放大器的输出参考噪声电流为2.5 $\text {nA}/\sqrt {\text {Hz}}$，在输出电流为9 $\text {mA}_{\text {p-p}}$的情况下，带宽为512 Hz，测量到的信噪比超过105.2 dB。

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 open journal of circuits and systems

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审稿时长

19 weeks