1,346 research outputs found
Energy-Efficient PRBS Impedance Spectroscopy on a Digital Versatile Platform
partially_open6siThis research has been partially funded by the Italian Ministry of University and Research (MUR) through the program “Dipartimenti di Eccellenza” (2018-2022). The research has also received partial support from the Italian Ministry of University and Research (MUR) and the Eranet FLAG ERA initiative within CONVERGENCE project (CUP B84I16000030005) through the IUNET Consortium.This paper presents the digital design of a versatile and low-power broadband impedance spectroscopy (IS) system based on pseudo-random binary sequence (PRBS) excitation. The PRBS technique allows fast, and low-power estimation of the impedance spectrum over a wide bandwidth with adequate accuracy, proving to be a good candidate for portable medical devices, especially. This paper covers the low-power design of the firmware algorithms and implements them on a versatile and reconfigurable digital platform that can be easily adjusted to the specific application. It will analyze the digital platform with the aim of reducing power consumption while maintaining adequate accuracy of the estimated spectrum. The paper studies two main algorithms (time-domain and frequency-domain) used for PRBS-based IS and implements both of them on the ultra-low-power GAP-8 digital platform. They are compared in terms of accuracy, measurement time, and power budget, while general design trade-offs are drawn out. The time-domain algorithm demonstrated the best accuracy while the frequency-domain one contributes more to save power and energy. However, analysis of the energy-per-error FOM revealed that the time-domain algorithm outperforms the frequency-domain algorithm offering better accuracy for the same energy consumption. Numerical methods and microprocessor resources are exploited to optimize the implementation of both algorithms achieving 27 ms in processing time, power consumption as low as 1.4 mW and a minimum energy consumption per measurement of 0.5 mJ, for a dense impedance spectrum estimation of 214 points.embargoed_20210525Luciani G.; Crescentini M.; Romani A.; Chiani M.; Benini L.; Tartagni M.Luciani G.; Crescentini M.; Romani A.; Chiani M.; Benini L.; Tartagni M
Crexens™: an expandable general-purpose electrochemical analyzer
2019 Fall.Includes bibliographical references.Electrochemical analysis has gained a great deal of attention of late due to its low-cost, easy-to-perform, and easy-to-miniaturize, especially in personal health care where accuracy and mobility are key factors to bring diagnostics to patients. According to data from Centers for Medicare & Medicaid Services (CMS) in the US, the share of health expenditure in the US has been kept growing in the past 3 decades and reached 17.9% of its overall Gross Domestic Product till 2016, which is equivalent to 5,000 each or above. Secondly, most of the instruments do not have good integration level that can perform different types of electrochemical measurements for different applications. The last but not the least, the existing generic benchtops instruments for electrochemical measurements have complex operational procedures that require users to have a sufficient biochemistry and electrochemistry background to operate them correctly. The proposed Crexens™ analyzer platform is aimed to present an affordable electrochemical analyzerwhile achieving comparable performance to the existing commercial instruments, thus, making general electrochemical measurement applications accessible to general public. In this dissertation, the overall Crexens™ electrochemical analyzer architecture and its evolution are presented. The foundation of the Crexens™ architecture was derived from two separate but related research in electrochemical sensing. One of them is a microelectrode sensor array using CMOS for neurotransmitter sensing; the other one is a DNA affinity-based capacitive sensor for infectious disease, such as ZIKA. The CMOS microelectrode sensor array achieved a 320uM sensitivity for norepinephrine, whereas the capacitive sensor achieved a dynamic range of detection from 1 /uL to 105 /uL target molecules (20 to 2 million targets), which makes it be within the detection range in a typical clinical application environment. This dissertation also covers the design details of the CMOS microelectrode array sensor and the capacitive sensor design as a prelude to the development of the Crexens™ analyzer architecture. Finally, an expandable integrated electrochemical analyzer architecture (Crexens™) has been designed for mobile point-of-care (POC) applications. Electrochemical methods have been explored in detecting various bio-molecules such as glucose, lactate, protein, DNA, neurotransmitter, steroid hormone, which resulted in good sensitivity and selectivity. The proposed system is capable of running electrochemical experiments including cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS), electrochemical capacitive spectroscopy (ECS), amperometry, potentiometry, and other derived electrochemical based tests. This system consist of a front-end interface to sensor electrodes, a back-end user interface on smart phone and PC, a base unit as master module, a low-noise add-on module, a high-speed add-on module, and a multi-channel add-on module. The architecture allows LEGO™-like capability to stack add-on modules on to the base-unit for performance enhancements in noise, speed or parallelism. The analyzer is capable of performing up to 1900 V/s CV with 10 mV step, up to 12 kHz EIS scan range and a limit of detection at 637 pA for amperometric applications with the base module. With high performance module, the EIS scan range can be extended upto 5 MHz. The limit of detection can be further improved to be at 333 fA using the low-noise module. The form factor of the electrochemical analyzer is designed for its mobile/point-of-care applications, integrating its entire functionality on to a 70 cm² area of surface space. A glutamine enzymatic sensor was used to valid the capability of the proposed electrochemical analyzer and turned out to give good linearity and reached a limit of detection at 50 uM
Une plate-forme sans fil pour electrochimique spectroscopie d'impédance
Avec l’émergence soutenue de capteurs et de dispositifs électrochimiques innovants, la spectroscopie d'impédance électrochimique est devenue l'un des outils les plus importants pour la caractérisation et la modélisation de la matière ionique et de l'interfaçage des capteurs. La capacité de détecter automatiquement, à l’aide de dispositifs électrochimiques peu couteux, les caractéristiques physiques et chimiques de la matière ionique ouvre une gamme d’application très variée pour la compréhension et l’optimisation des procédés ou interviennent les processus électrochimiques. Cette thèse décrit le développement d’une plate-forme microélectronique miniaturisée, connectée, multiplexée, et à faible coût pour la spectroscopie d'impédance diélectrique (SID) conçue pour les mesures électrochimiques in-situ et adaptée aux architectures de réseau sans fil. La plate-forme développée durant ce travail de maitrise a été testée et validée au sein d’une maille ZigBee et a été en mesure d'interfacer jusqu'à trois capteurs SID en même temps et de relayer l'information à travers le net Zigbee pour l'analyse de données et le stockage. Le système a été construit à partir de composants microélectroniques disponibles commercialement et bénéficie des avantages d'une calibration système on-the-fly qui effectue la calibration du capteur de manière aisée. Dans ce mémoire de maitrise, nous rapportons la modélisation et la caractérisation de senseurs électrochimiques de nitrate; notamment nous décrivons la conception microélectronique, la réponse d'impédance de Nyquist, la sensibilité et la précision de la mesure électrochimique, et les résultats de tests de la plate-forme pour les applications de spectroscopie d'impédance relatives à la détection du nitrate, de la détection de la qualité de l'eau, et des senseurs tactiles.The emergence of the various applications of electrochemical sensors and devices, electrochemical impedance spectroscopy became one of the most important tools for characterizing and modeling of the material and interfacing the sensors. The ability to sense in an automatic manner enables a wide variety of processes to be better understood and optimized cost-effectively. This thesis describes the development of a low-cost, miniaturized, multiplexed, and connected platform for dielectric impedance spectroscopy (DIS) designed for in-situ measurements and adapted to wireless network architectures. The platform has been tested and used as a DIS sensor node on a ZigBee mesh and was able to interface up to three DIS sensors at the same time and relay the information through the Zigbee net for data analysis and storage. The system was built from commercial microelectronics components and benefits from an on-the-fly calibration system that makes sensor calibration easy. The thesis reports characterizing and modeling of two electro-chemical devices (i.e. nitrate sensor and optically-transparent electrically-conductive glasses) and also describes the microelectronics design, the Nyquist impedance response, the measurement sensitivity and accuracy, and the testing of the platform for in-situ dielectric impedance spectroscopy applications pertaining to fertilizer sensing, water quality sensing, and touch sensing
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Techniques in Optical Coherence and Resonance for Sensing
Optical sensors are ubiquitous for their precision and non-contact acquisition, and have enjoyed widespread use in applications such as biosensing, environmental monitoring, and security. Despite their sensitivity, many of these sensors rely on costly laboratory instrumentation, and are not adaptable to the ever-growing volume of consumer detectors and optics that are readily available, making their application limited to benchtop analytics. This work leverages plasmonic resonances and optical coherence phenomena to make modifications upon traditional sensing formats that improve their sensitivity when deployed in off-the-shelf optical systems. In particular, we demonstrate that label-free plasmonic sensors can be combined with electrochemical impedance spectroscopic biosensors to tackle the problem of specificity in label-free sesning, demonstrate the novel use case for the plasmonic detection of thermal infrared radiation, and show that plasmonic imaging is conducive to the characterization of nanometric thin liquid films. Moreover, we show that by introducing limited dispersion to Fourier transform spectroscopy, we can efficiently use camera detector formats and imaging systems to implement a high resolution scan-less Fourier transform spectrometer. By improving the figures of merit for sensor devices, we aim to translate traditional analytical sensing instrumentation from the laboratory benchtop into the consumer marketplace, and to spearhead a host of new applications
III–V-on-silicon photonic integrated circuits for spectroscopic sensing in the 2–4 μm wavelength range
The availability of silicon photonic integrated circuits (ICs) in the 2-4 mu m wavelength range enables miniature optical sensors for trace gas and bio-molecule detection. In this paper, we review our recent work on III-V-on-silicon waveguide circuits for spectroscopic sensing in this wavelength range. We first present results on the heterogeneous integration of 2.3 mu m wavelength III-V laser sources and photodetectors on silicon photonic ICs for fully integrated optical sensors. Then a compact 2 mu m wavelength widely tunable external cavity laser using a silicon photonic IC for the wavelength selective feedback is shown. High-performance silicon arrayed waveguide grating spectrometers are also presented. Further we show an on-chip photothermal transducer using a suspended silicon-on-insulator microring resonator used for mid-infrared photothermal spectroscopy
Terahertz Technology and Its Applications
The Terahertz frequency range (0.1 – 10)THz has demonstrated to provide many opportunities in prominent research fields such as high-speed communications, biomedicine, sensing, and imaging. This spectral range, lying between electronics and photonics, has been historically known as “terahertz gap” because of the lack of experimental as well as fabrication technologies. However, many efforts are now being carried out worldwide in order improve technology working at this frequency range. This book represents a mechanism to highlight some of the work being done within this range of the electromagnetic spectrum. The topics covered include non-destructive testing, teraherz imaging and sensing, among others
CMOS Design of Reconfigurable SoC Systems for Impedance Sensor Devices
La rápida evolución en el campo de los sensores inteligentes, junto con los avances en las tecnologías de la computación y la comunicación, está revolucionando la forma en que recopilamos y analizamos datos del mundo físico para tomar decisiones, facilitando nuevas soluciones que desempeñan tareas que antes eran inconcebibles de lograr.La inclusión en un mismo dado de silicio de todos los elementos necesarios para un proceso de monitorización y actuación ha sido posible gracias a los avances en micro (y nano) electrónica. Al mismo tiempo, la evolución de las tecnologías de procesamiento y micromecanizado de superficies de silicio y otros materiales complementarios ha dado lugar al desarrollo de sensores integrados compatibles con CMOS, lo que permite la implementación de matrices de sensores de alta densidad. Así, la combinación de un sistema de adquisición basado en sensores on-Chip, junto con un microprocesador como núcleo digital donde se puede ejecutar la digitalización de señales, el procesamiento y la comunicación de datos proporciona características adicionales como reducción del coste, compacidad, portabilidad, alimentación por batería, facilidad de uso e intercambio inteligente de datos, aumentando su potencial número de aplicaciones.Esta tesis pretende profundizar en el diseño de un sistema portátil de medición de espectroscopía de impedancia de baja potencia operado por batería, basado en tecnologías microelectrónicas CMOS, que pueda integrarse con el sensor, proporcionando una implementación paralelizable sin incrementar significativamente el tamaño o el consumo, pero manteniendo las principales características de fiabilidad y sensibilidad de un instrumento de laboratorio. Esto requiere el diseño tanto de la etapa de gestión de la energía como de las diferentes celdas que conforman la interfaz, que habrán de satisfacer los requisitos de un alto rendimiento a la par que las exigentes restricciones de tamaño mínimo y bajo consumo requeridas en la monitorización portátil, características que son aún más críticas al considerar la tendencia actual hacia matrices de sensores.A nivel de celdas, se proponen diferentes circuitos en un proceso CMOS de 180 nm: un regulador de baja caída de voltaje como unidad de gestión de energía, que proporciona una alimentación de 1.8 V estable, de bajo ruido, precisa e independiente de la carga para todo el sistema; amplificadores de instrumentación con una aproximación completamente diferencial, que incluyen una etapa de entrada de voltaje/corriente configurable, ganancia programable y ancho de banda ajustable, tanto en la frecuencia de corte baja como alta; un multiplicador para conformar la demodulación dual, que está embebido en el amplificador para optimizar consumo y área; y filtros pasa baja totalmente integrados, que actúan como extractores de magnitud de DC, con frecuencias de corte ajustables desde sub-Hz hasta cientos de Hz.<br /
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