Your search keyword '"Radogna, Antonio Vincenzo"' showing total 2 results

1. A 177 ppm RMS Error-Integrated Interface for Time-Based Impedance Spectroscopy of Sensors.

Author

Radogna, Antonio Vincenzo, Capone, Simonetta, Francioso, Luca, Siciliano, Pietro Aleardo, and D'Amico, Stefano

Subjects

IMPEDANCE spectroscopy, CIRCUIT complexity, RANDOM access memory, SIGNAL processing, ELECTRIC impedance, TIME-resolved spectroscopy

Abstract

This paper presents an integrated circuit for time-based electrical impedance spectroscopy (EIS) of sensors. The circuit exploits maximum-length sequences (MLS) in order to perform a broadband excitation of the sensors under test. Therefore, the measured time-domain EIS is obtained by cross-correlating the input with the output of the analog front end (AFE). Unlike the conventional digital approach, the cross-correlation operation is performed in the analog domain. This leads to a lower RMS error in the measured time-domain EIS since the signal processing is not affected by the quantization noise of the analog-to-digital converter (ADC). It also relaxes the sampling frequency of the ADC leading, along with the lack of random access memory (RAM) usage, to a reduced circuit complexity. Theoretical concepts about the circuit's design and operation are presented, with an emphasis on the thermal noise phenomenon. The simulated performances are shown by testing a sensor's equivalent model composed of a 50 kΩ resistor in parallel with a 100 p F capacitor. A time-based EIS output of 255 points was obtained with a maximum tested frequency of 500 k Hz and a simulated RMS error of 0.0177% (or 177 ppm). [ABSTRACT FROM AUTHOR]

Published

2022

2. Performance Analysis of an MLS-Based Interface for Impulse Response Estimation of Resistive and Capacitive Sensors.

Author

Radogna, Antonio Vincenzo, Capone, Simonetta, Francioso, Luca, Siciliano, Pietro Aleardo, and D'Amico, Stefano

Subjects

*IMPULSE response, *CAPACITIVE sensors, *MEASUREMENT errors, *ELECTROCHEMICAL analysis, *IMPEDANCE spectroscopy, *LENGTH measurement

Abstract

This paper presents a performance analysis of a system for electrochemical impedance spectroscopy (EIS). The system, composed by an analog front-end (AFE) and a custom microcontroller (MCU) board, performs the impulse response (IR) measurement of linear and time-invariant (LTI) systems with pseudo-random excitation signals. As a novelty, a specific AFE for the interfacing of two-terminal resistive and capacitive sensors is covered in detail. The paper proposes, for the first time, a mathematical model to predict the impact of the main noise sources in the measured IR. Thanks to the proposed approach, the AFE and the system’s parameters can be properly designed in order to reduce the error, thus, minimizing the energy-per-error figure of merit (FOM) as well. The AFE is realized as discrete-components circuit and it has been included in a custom MCU-based measurement system as an expansion module. The predicted results from the mathematical model, in terms of noise power, SNR, and measurement error are validated through system-level simulation and experimental measurements. The system performs the IR measurement with 1023 points, showing root-mean-square (RMS) measurement errors of 1% and 1.4% for the tested ADC sampling frequencies of 62.5 kHz and 125 kHz, respectively. These lead to excellent FOM values of 128.9 mJ $\cdot $ %2 and 252.6 mJ $\cdot $ %2 that outstand the state of the art. [ABSTRACT FROM AUTHOR]

Published

2022