OPTIMIZATION OF BALANCING IN A BRIDGE MEASURING CIRCUIT WITH A DIFFERENTIAL CONDUCTOMETRIC SENSOR

Q3 Energy

Technical Electrodynamics Pub Date : 2022-07-04 DOI:10.15407/techned2022.04.078

V. Melnyk, P. Borshchov, O. Vasylenko, I.O. Brahynets

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引用次数: 2

Abstract

The article is devoted to solving the problem of the occurrence of an additive error in determining local changes in the electrical conductivity of electrolyte solutions under conditions of changes in the background electrical conductivity of the measurement medium, which often occurs in biosensor and other systems with a differential pair of conductometric transducers, if their electrical parameters are not identical. The goal is to provide a deep suppression of the influence of background changes with significant differences in both reactance and active resistance in the transducers of a pair of sensor. The essence of the issue, the causes and mechanism of this type of error, as well as the methods and means of its reduction, developed earlier, are briefly considered. A diagram and description of the structure of a differential conductometric channel of a biosensor system based on an AC bridge, an algorithm for its balancing operations by controlling the module and phase of the test voltage, as well as a vector diagram of currents and voltages in the bridge circuit during this process. The balancing of the bridge has been was modeled analytically, bringing it to a quasi-equilibrium state, in which changes in the background electrical conductivity do not change its output signal. Additional operations for balancing the bridge are determined to achieve such a state with significant differences in both capacitances and active resistances in the impedances of a pair of conductometric transducers of a differential sensor. The results of experimental studies of the suppression of the influence of changes in the background electrical conductivity of a solution in a differential conductometric channel with using its computer model and experimental sample of a conductometric instrument with an electrical equivalent of a differential sensor are presented. A comparison of the results obtained and the corresponding data for balancing bridge circuits by previously developed methods is given. References 16, figures 3, tables 3.

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差分电导传感器桥式测量电路平衡的优化

本文致力于解决在测量介质的背景电导率变化的条件下，在确定电解质溶液电导率的局部变化时发生加性误差的问题，这种问题经常发生在生物传感器和其他具有差分对电导率传感器的系统中，如果它们的电学参数不相同。目标是对一对传感器的换能器中电抗和有源电阻的显著差异的背景变化的影响提供深度抑制。本文简要地审议了问题的实质、这类误差的原因和机制，以及早先制定的减少误差的方法和手段。给出了基于交流电桥的生物传感器系统差分电导通道的结构示意图和描述，通过控制测试电压的模块和相位实现其平衡操作的算法，以及在此过程中电桥电路中电流和电压的矢量图。对电桥的平衡进行了解析建模，使其达到准平衡状态，在这种状态下，背景电导率的变化不会改变其输出信号。平衡电桥的额外操作被确定为达到这样一种状态，在差分传感器的一对电导换能器的阻抗中，电容和有源电阻都有显著差异。本文介绍了差分电导通道中溶液背景电导率变化的抑制实验研究结果，并利用差分电导通道的计算机模型和具有等效差分传感器的电导仪器的实验样品进行了实验研究。并将所得到的结果与以往的桥式电路平衡方法进行了比较。参考文献16，图3，表3。

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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