An Improved Zero Potential Circuit for Readout of a Two-Dimensional Resistive Sensor Array

Wu, Jianfeng; Wang, Feng; Wang, Qi; Li, Jianqing; Song, Aiguo

doi:10.3390/s16122070

Cited by 12 publications

(4 citation statements)

References 27 publications

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“…Finally, Circuit E, as proposed by Wu et al [21], is a ZP circuit that enhances the setting non-scanned-electrode zero potential circuit (S-NSE-ZPC) proposed by Liu et al [12]. In this case, two operational amplifiers are used to ensure the same ZP difference between all the non-scanned elements.…”

Section: Circuits For Scanning Of Resistive Sensor Arraymentioning

confidence: 99%

Crosstalk Error Analysis in IIDFC Readout Circuit for Use in Piezoresistive Composite

et al. 2018

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Resistive sensor arrays (RSAs) have been developed for a variety of applications depending on resolution requirements, active sensor area, and cost. Composite-based piezoresistive sensors are commonly found in RSAs. However, they present an intrinsic problem related to the parasitic current paths that flow through the whole composite, which cause a crosstalk effect. Various circuits have been proposed to reduce the crosstalk effect in sensor arrays. In this paper, we compare a number of readout circuits with PSpice models, mainly those including voltage feedback (VF) circuits and zero potential (ZP) circuits. To develop an array with 3600 sensors using a piezoresistive composite, we selected the improved isolated drive feedback circuit (IIDFC). Using nodal analysis, we were able to develop an alternative mathematical circuit model, which allowed us to identify its unique characteristics, including the influence of array size on the crosstalk effect and the restriction on minimal impedance that the array elements must attain to maintain a minimum error. In a resistive array with 3600 sensors and a sensor range of 10-100 k , we obtained an absolute error of less than 3.56%. In addition, the proposed mathematical circuit model obtained a maximum absolute error difference of 0.03% when compared with the PSpice model with the precision operational amplifier OPA37. Thus, using the IIDFC circuit and considering the minimal allowable impedance, it is possible to maintain a reduced error in an RSA with a large number of sensors.

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Section: Circuits For Scanning Of Resistive Sensor Arraymentioning

confidence: 99%

Crosstalk Error Analysis in IIDFC Readout Circuit for Use in Piezoresistive Composite

et al. 2018

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“…Also, it can be a virtual zero potential (V Vzp ) for the Amp Zp and the R cg (as shown in the shadow part in Fig. 1b) [23]. The currents (I Lx , x = 1, …, M) of the feedback resistors (R Lx , x = 1, …, M) are injected into the row electrodes of the resistive sensor array.…”

Section: Design and Principle Analyses Of Ifrzpcmentioning

confidence: 99%

Improved FRZPC for the two‐dimensional resistive sensor array

Wang

Wen

Pan

et al. 2018

IET Science, Measurement & Technology

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“…Errors of over 40% can occur, depending on the type of resistor to be measured, and even using two readout circuits to minimise errors [29]. The occurrence of phantom (but unquantified) pressures was observed for different pressure patterns in a previous study [19] for a 6 × 6 array of tactile sensors.…”

Section: Introductionmentioning

confidence: 99%

High-Accuracy Readout Electronics for Piezoresistive Tactile Sensors

Hidalgo-López

Oballe-Peinado

Castellanos-Ramos

et al. 2017

Sensors

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The typical layout in a piezoresistive tactile sensor arranges individual sensors to form an array with M rows and N columns. While this layout reduces the wiring involved, it does not allow the values of the sensor resistors to be measured individually due to the appearance of crosstalk caused by the nonidealities of the array reading circuits. In this paper, two reading methods that minimize errors resulting from this phenomenon are assessed by designing an electronic system for array reading, and the results are compared to those obtained using the traditional method, obviating the nonidealities of the reading circuit. The different models were compared by testing the system with an array of discrete resistors. The system was later connected to a tactile sensor with 8 × 7 taxels.

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An Improved Zero Potential Circuit for Readout of a Two-Dimensional Resistive Sensor Array

Cited by 12 publications

References 27 publications

Crosstalk Error Analysis in IIDFC Readout Circuit for Use in Piezoresistive Composite

Crosstalk Error Analysis in IIDFC Readout Circuit for Use in Piezoresistive Composite

Improved FRZPC for the two‐dimensional resistive sensor array

High-Accuracy Readout Electronics for Piezoresistive Tactile Sensors

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