Abstract
This paper presents optimization criteria for an integrated switched-capacitor front-end circuit for capacitive sensors with a wide dynamic range. The principle of the interface is based on the use of a relaxation oscillator. A negative-feedback circuit controls the charge-transfer speed to prevent the overload of the input amplifier for large input signals which thus enables a wide dynamic range of capacitor values. Moreover, it has been shown that the use of negative feedback can also result in much better noise performance. However, for the interface to function properly, there is a serious limitation for the value of a specific parasitic capacitance. Therefore, a method which extends the acceptable range of this parasitic capacitance is proposed. A novel method of linearity measurement which takes the influence of PCB parasitic capacitances into account, is also presented. The circuit has been designed and implemented in 0.7 mum standard CMOS technology. The supply voltage is 5 V and the measured value for the supply current is about 1.4 mA. Experimental results show that for the capacitor range of 1 pF to 300 pF, application of negative feedback yields a linearity of about 50 x10 <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">-6</sup> (14 bits) with a 16-bit resolution for a measurement time of 100 ms. Tests have been performed over the temperature range from to .
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