Guest Editorial Circuits and Systems for Smart Agriculture and Healthy Foods

This Special Issue of the IEEE JOURNAL ON EMERGING AND SELECTED TOPICS IN CIRCUITS AND SYSTEMS (JETCAS) is dedicated to Circuits and Systems applied to innovative products for the Agriculture and Food value chain

Guest editorial: Special issue on selected papers from IEEE BioCAS 2018

The papers in this special section were presented at the 2018 IEEE Biomedical Circuits and Systems Conference (BioCAS 2018) that was held in in Cleveland, OH, from October 17–19, 2018

Combined HW/SW Drift and Variability Mitigation for PCM-based Analog In-memory Computing for Neural Network Applications

Matrix-Vector Multiplications (MVMs) represent a heavy workload for both training and inference in Deep Neural Networks (DNNs) applications. Analog In-memory Computing (AIMC) systems based on Phase Change Memory (PCM) has been shown to be a valid competitor to enhance the energy efficiency of DNN accelerators. Although DNNs are quite resilient to computation inaccuracies, PCM non-idealities could strongly affect MVM operations precision, and thus the accuracy of DNNs. In this paper, a combined hardware and software solution to mitigate the impact of PCM non-idealities is presented. The drift of PCM cells conductance is compensated at the circuit level through the introduction of a conductance ratio at the core of the MVM computation. A model of the behaviour of PCM cells is employed to develop a device-aware training for DNNs and the accuracy is estimated in a CIFAR-10 classification task. This work is supported by a PCM-based AIMC prototype, designed in a 90-nm STMicroelectronics technology, and conceived to perform Multiply-and-Accumulate (MAC) computations, which are the kernel of MVMs. Results show that the MAC computation accuracy is around 95% even under the effect of cells drift. The use of a device-aware DNN training makes the networks less sensitive to weight variability, with a 15% increase in classification accuracy over a conventionally-trained Lenet-5 DNN, and a 36% gain when drift compensation is applied

Streaming Algorithms for Subspace Analysis: Comparative Review and Implementation on IoT Devices

Subspace analysis is a widely used technique for coping with high-dimensional data and is becoming a fundamental step in the early treatment of many signal processing tasks. However, traditional subspace analysis often requires a large amount of memory and computational resources, as it is equivalent to eigenspace determination. To address this issue, specialized streaming algorithms have been developed, allowing subspace analysis to be run on low-power devices such as sensors or edge devices. Here, we present a classification and a comparison of these methods by providing a consistent description and highlighting their features and similarities. We also evaluate their performance in the task of subspace identification with a focus on computational complexity and memory footprint for different signal dimensions. Additionally, we test the implementation of these algorithms on common hardware platforms typically employed for sensors and edge devices

Passive impedance sensing using a SAW resonator-coupled biosensor for zero-power wearable applications

A bio-sensing scheme, which acquires impedance information of a capacitive biosensor by using the reflected RF signal from a surface acoustic wave (SAW) resonator connected to the biosensor, is proposed. This technique requires no power to be supplied to the biosensor node and hence is highly applicable to wearable applications. Theoretical analysis has demonstrated that the sensitivity of the SAW resonator-coupled biosensor is higher than that of traditional impedance loaded SAW sensors and therefore it is more suitable for measuring the very small impedance changes in biosensors. The passive detection of the change in the impedance of a capacitive biosensor, as a result of biological binding events associated with the capture of a target analyte, has been demonstrated by preliminary experimentation. Dry tests of the SAW coupled capacitive biosensor using a cable connected network analyzer showed the aF level capacitance measurement resolution, which was only achieved in transistor level circuits previously, could be attained. When liquid samples with concentrations of C-Reactive Protein (CRP) in the range of 0.1 to 2 μg/ml were applied to the biosensor, a corresponding change in the resonant frequency of the SAW resonator-coupled biosensor (in the order of sub-hundred kHz) was observed. This has demonstrated the potential for applying this technique in applications where a zero-power requirement at the biosensor node could be a distinct advantage, when the cable link between the network analyzer and the biosensor node is replaced by the RF transmission

Analog Compressive Sensing for Multi-Channel Neural Recording: Modeling and Circuit Level Implementation

RÉSUMÉ Dans cette thèse, nous présentons la conception d’un implant d’enregistrement neuronal multicanaux avec un échantillonnage compressé mis en oeuvre avec un procédé de fabrication CMOS à 65 nm. La réduction de la technologie a˙ecte à la baisse les paramètres des amplificateurs neuronaux couplés en AC, comme la fréquence de coupure basse, en raison de l’e˙et de canal court des transistors MOS. Nous analysons la fréquence de coupure basse et nous constatons que l’origine de ce problème, dans les technologies avancées, est la diminution de l’impédance d’entrée de l’amplificateur opérationnel de transconductance (OTA) en raison de la fuite d’oxyde de grille à l’entrée des OTA. Nous proposons deux solutions pour réduire la fréquence de coupure basse sans augmenter la valeur des condensateurs de rétroaction de l’étage d’entrée. La première solution est appelée rétroaction positive croisée et la deuxième solution utilise des PMOS à oxyde épais dans la paire de l’entrée di˙érentielle de l’OTA. Il est à noter que pour compresser le signal neuronal, nous utilisons le CS dans le domaine analogique. Pour la réalisation, un intégrateur à capacité commutée est requis. Les paramètres non idéaux de l’OTA utilisé dans cet intégrateur, tels que le gain fini, la bande passante, la vitesse de balayage et le changement rapide de la sortie. Toutes ces imperfections induisent des erreurs et réduisent le rapport signal sur bruit (SNR) total. Nous avons simulé ces imperfections sur Matlab et Simulink pour définir les spécifications de l’OTA requis. Aussi, pour concevoir les circuits analogiques correspondant aux interfaces neuronales requises, tels qu’un amplificateur neuronal, une référence de tension compacte et à faible consommation d’énergie est requise. Nous avons proposé une référence de tension de faible consommation d’énergie sans utiliser le transistor bipolaire parasite de la technologie CMOS pour diminuer la surface de silicium requise. Finalement, nous avons complété l’encodeur de CS et un convertisseur analogique-numérique à approximation successive (SAR ADC) requis pour la chaine d’enregistrement des signaux neuronaux dans ce projet.----------ABSTRACT In this thesis we present the design of a multi-channel neural recording implant with analog compressive sensing (CS) in 65 nm process. Scaling down technology demotes the parameters of AC-coupled neural amplifiers, such as increasing the low-cuto˙ frequency due to the short-channel e˙ects of MOS transistors. We analyze the low-cuto˙ frequency and find that the main reason of this problem in advanced technologies is decreasing the input resistance of the operational transconductance amplifier (OTA) due to the gate oxide static current leakage in the input of the OTA. In advanced technologies, the gate oxide is thin and some electrons can penetrate to the channel and cause DC current leakage. We proposed two solutions to reduce the low-cuto˙ frequency without increasing the value of the feedback capacitors of the front-end neural amplifier. The first solution is called cross-coupled positive feedback, and the second solution is utilizing thick-oxide PMOS transistors in the input di˙erential pair of the OTA. Compress the neural signal, we utilized the CS method in analog domain. For its implementation, a switched-capacitor integrator is required. Non-ideal specifications of OTA of CS integrator such as finite gain, bandwidth, slew rate and output swing induce error and reduce the total signal to noise ratio (SNR). We simulated these non-idealities in Matlab and Simulink and extracted the specification of the required OTA. Also, to design analog circuits such as neural amplifier a low power and compact voltage reference is required. We implemented a low-power band-gap reference without utilizing parasitic bipolar transis-tor to decrease the silicon area. At the end, we completed the CS encoder and successive approximation architecture analog-to-digital converter (SAR ADC)

Neuromorphic Computing between Reality and Future Needs

Neuromorphic computing is a one of computer engineering methods that to model their elements as the human brain and nervous system. Many sciences as biology, mathematics, electronic engineering, computer science and physics have been integrated to construct artificial neural systems. In this chapter, the basics of Neuromorphic computing together with existing systems having the materials, devices, and circuits. The last part includes algorithms and applications in some fields

Applications in Electronics Pervading Industry, Environment and Society

This book features the manuscripts accepted for the Special Issue “Applications in Electronics Pervading Industry, Environment and Society—Sensing Systems and Pervasive Intelligence” of the MDPI journal Sensors. Most of the papers come from a selection of the best papers of the 2019 edition of the “Applications in Electronics Pervading Industry, Environment and Society” (APPLEPIES) Conference, which was held in November 2019. All these papers have been significantly enhanced with novel experimental results. The papers give an overview of the trends in research and development activities concerning the pervasive application of electronics in industry, the environment, and society. The focus of these papers is on cyber physical systems (CPS), with research proposals for new sensor acquisition and ADC (analog to digital converter) methods, high-speed communication systems, cybersecurity, big data management, and data processing including emerging machine learning techniques. Physical implementation aspects are discussed as well as the trade-off found between functional performance and hardware/system costs

Wearable Wireless Devices

No abstract available