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低电压电泳芯片非接触电导检测电路设计(英文) 被引量:1

Design of contactless conductivity detecting circuit for electrophoresis chip
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摘要 根据低电压集成电泳芯片柱端非接触高频电导器的结构和非接触高频电导检测的基本原理,设计了非接触电导检测电路。该电路包括AC激励信号发生器、I-V转换器、乘法运算器、低通滤波器和差分放大器。运用较少的元器件和较简单的电路形式实现了检测功能,解决了低电压电泳芯片微弱的非接触电导信号检测困难的问题。通过调节电路参数分别得到了频率为450kHz和1MHz,幅值为10V的正弦信号。在此激励信号下,在集成低电压电泳芯片上对一系列不同浓度的K+溶液进行了非接触电导响应信号的测试。实验结果表明,电路能分辨的离子浓度的下限为10-9;离子浓度为10-9~10-5时,电路响应具有很高的线性度和分辨率。该电路亦可用于其它微弱电导信号检测领域。 On the basis of the structure of a pole conductivity detector for an integrated low voltage electrophoresis chip, a contactless conductivity detecting circuit is designed according to the working principle of high frequency contactless conductivity detecting,which consists of an AC inspiriting signal generator,a I-V convertor, a multiplicator,a low-pass filter and a differential amplifier. By using less devices and simple structures to realize powerful detecting, the circuit resolves the problem difficult to detect the very weak signals of low voltage electrophoresis chips. Finally,a test is applied to a electrophoresis chip to detect the contactless conductance signals of different concentrations of K^+ by using the detecting circuit with an AC inspiriting signal of 10 V and the inspiriting frequencies of 450 kHz and 1 MHz. The experimental results show that the circuit can distinguish the lowest concentra-tion of 10^-9,and can reach the high linearity and resolution power in the ranges of 10^-9-10^-5. For its detecting functions, this circuit is able to used in other conductivity detecting fields.
作者 刘海涛 温志渝 徐溢 梁静 杨玉发
机构地区 重庆大学微纳器件与系统国家重点学科实验室 重庆大学微纳系统与新材料技术国家级国际联合研究中心 重庆大学微系统研究中心
出处 《光学精密工程》 EI CAS CSCD 北大核心 2009年第7期1640-1645,共6页 Optics and Precision Engineering
基金 Supported by the National High-Tech Research and Development Program of China(863 Program)(Grant No.2006AA04Z354)
关键词 电泳芯片 非接触电导 检测电路 I-V转换 乘法运算 低通滤波 electrophoresis chip contactless conductivity detecting circuit I-V conversion multiplication low-pass filtering
分类号 TN710.9 [电子电信—电路与系统]
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光学精密工程
2009年 第7期

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