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348 results on '"Benatti, Simone"'

1. GAPses: Versatile smart glasses for comfortable and fully-dry acquisition and parallel ultra-low-power processing of EEG and EOG

Author

Frey, Sebastian, Lucchini, Mattia Alberto, Kartsch, Victor, Ingolfsson, Thorir Mar, Bernardi, Andrea Helga, Segessenmann, Michael, Osieleniec, Jakub, Benatti, Simone, Benini, Luca, and Cossettini, Andrea

Subjects
Electrical Engineering and Systems Science - Signal Processing, Electrical Engineering and Systems Science - Systems and Control
Abstract

Recent advancements in head-mounted wearable technology are revolutionizing the field of biopotential measurement, but the integration of these technologies into practical, user-friendly devices remains challenging due to issues with design intrusiveness, comfort, and data privacy. To address these challenges, this paper presents GAPSES, a novel smart glasses platform designed for unobtrusive, comfortable, and secure acquisition and processing of electroencephalography (EEG) and electrooculography (EOG) signals. We introduce a direct electrode-electronics interface with custom fully dry soft electrodes to enhance comfort for long wear. An integrated parallel ultra-low-power RISC-V processor (GAP9, Greenwaves Technologies) processes data at the edge, thereby eliminating the need for continuous data streaming through a wireless link, enhancing privacy, and increasing system reliability in adverse channel conditions. We demonstrate the broad applicability of the designed prototype through validation in a number of EEG-based interaction tasks, including alpha waves, steady-state visual evoked potential analysis, and motor movement classification. Furthermore, we demonstrate an EEG-based biometric subject recognition task, where we reach a sensitivity and specificity of 98.87% and 99.86% respectively, with only 8 EEG channels and an energy consumption per inference on the edge as low as 121 uJ. Moreover, in an EOG-based eye movement classification task, we reach an accuracy of 96.68% on 11 classes, resulting in an information transfer rate of 94.78 bit/min, which can be further increased to 161.43 bit/min by reducing the accuracy to 81.43%. The deployed implementation has an energy consumption of 24 uJ per inference and a total system power of only 16.28 mW, allowing for continuous operation of more than 12 h with a small 75 mAh battery., Comment: 10 pages, 5 figures, 5 tables. This paper has been submitted to IEEE Transactions on Biomedical Circuits and Systems

Published
2024

2. A Heterogeneous RISC-V based SoC for Secure Nano-UAV Navigation

Author

Valente, Luca, Nadalini, Alessandro, Veeran, Asif, Sinigaglia, Mattia, Sa, Bruno, Wistoff, Nils, Tortorella, Yvan, Benatti, Simone, Psiakis, Rafail, Kulmala, Ari, Mohammad, Baker, Pinto, Sandro, Palossi, Daniele, Benini, Luca, and Rossi, Davide

Subjects
Computer Science - Hardware Architecture, Computer Science - Artificial Intelligence
Abstract

The rapid advancement of energy-efficient parallel ultra-low-power (ULP) ucontrollers units (MCUs) is enabling the development of autonomous nano-sized unmanned aerial vehicles (nano-UAVs). These sub-10cm drones represent the next generation of unobtrusive robotic helpers and ubiquitous smart sensors. However, nano-UAVs face significant power and payload constraints while requiring advanced computing capabilities akin to standard drones, including real-time Machine Learning (ML) performance and the safe co-existence of general-purpose and real-time OSs. Although some advanced parallel ULP MCUs offer the necessary ML computing capabilities within the prescribed power limits, they rely on small main memories (<1MB) and ucontroller-class CPUs with no virtualization or security features, and hence only support simple bare-metal runtimes. In this work, we present Shaheen, a 9mm2 200mW SoC implemented in 22nm FDX technology. Differently from state-of-the-art MCUs, Shaheen integrates a Linux-capable RV64 core, compliant with the v1.0 ratified Hypervisor extension and equipped with timing channel protection, along with a low-cost and low-power memory controller exposing up to 512MB of off-chip low-cost low-power HyperRAM directly to the CPU. At the same time, it integrates a fully programmable energy- and area-efficient multi-core cluster of RV32 cores optimized for general-purpose DSP as well as reduced- and mixed-precision ML. To the best of the authors' knowledge, it is the first silicon prototype of a ULP SoC coupling the RV64 and RV32 cores in a heterogeneous host+accelerator architecture fully based on the RISC-V ISA. We demonstrate the capabilities of the proposed SoC on a wide range of benchmarks relevant to nano-UAV applications. The cluster can deliver up to 90GOp/s and up to 1.8TOp/s/W on 2-bit integer kernels and up to 7.9GFLOp/s and up to 150GFLOp/s/W on 16-bit FP kernels.

Published
2024
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3. A Wearable Ultra-Low-Power sEMG-Triggered Ultrasound System for Long-Term Muscle Activity Monitoring

Author

Frey, Sebastian, Kartsch, Victor, Leitner, Christoph, Cossettini, Andrea, Vostrikov, Sergei, Benatti, Simone, and Benini, Luca

Subjects
Electrical Engineering and Systems Science - Systems and Control, Electrical Engineering and Systems Science - Signal Processing
Abstract

Surface electromyography (sEMG) is a well-established approach to monitor muscular activity on wearable and resource-constrained devices. However, when measuring deeper muscles, its low signal-to-noise ratio (SNR), high signal attenuation, and crosstalk degrade sensing performance. Ultrasound (US) complements sEMG effectively with its higher SNR at high penetration depths. In fact, combining US and sEMG improves the accuracy of muscle dynamic assessment, compared to using only one modality. However, the power envelope of US hardware is considerably higher than that of sEMG, thus inflating energy consumption and reducing the battery life. This work proposes a wearable solution that integrates both modalities and utilizes an EMG-driven wake-up approach to achieve ultra-low power consumption as needed for wearable long-term monitoring. We integrate two wearable state-of-the-art (SoA) US and ExG biosignal acquisition devices to acquire time-synchronized measurements of the short head of the biceps. To minimize power consumption, the US probe is kept in a sleep state when there is no muscle activity. sEMG data are processed on the probe (filtering, envelope extraction and thresholding) to identify muscle activity and generate a trigger to wake-up the US counterpart. The US acquisition starts before muscle fascicles displacement thanks to a triggering time faster than the electromechanical delay (30-100 ms) between the neuromuscular junction stimulation and the muscle contraction. Assuming a muscle contraction of 200 ms at a contraction rate of 1 Hz, the proposed approach enables more than 59% energy saving (with a full-system average power consumption of 12.2 mW) as compared to operating both sEMG and US continuously., Comment: 4 pages, 5 figures, 1 table, 2023 IEEE International Ultrasonics Symposium

Published
2023

4. EpiDeNet: An Energy-Efficient Approach to Seizure Detection for Embedded Systems

Author

Ingolfsson, Thorir Mar, Chakraborty, Upasana, Wang, Xiaying, Beniczky, Sandor, Ducouret, Pauline, Benatti, Simone, Ryvlin, Philippe, Cossettini, Andrea, and Benini, Luca

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Human-Computer Interaction, Computer Science - Machine Learning
Abstract

Epilepsy is a prevalent neurological disorder that affects millions of individuals globally, and continuous monitoring coupled with automated seizure detection appears as a necessity for effective patient treatment. To enable long-term care in daily-life conditions, comfortable and smart wearable devices with long battery life are required, which in turn set the demand for resource-constrained and energy-efficient computing solutions. In this context, the development of machine learning algorithms for seizure detection faces the challenge of heavily imbalanced datasets. This paper introduces EpiDeNet, a new lightweight seizure detection network, and Sensitivity-Specificity Weighted Cross-Entropy (SSWCE), a new loss function that incorporates sensitivity and specificity, to address the challenge of heavily unbalanced datasets. The proposed EpiDeNet-SSWCE approach demonstrates the successful detection of 91.16% and 92.00% seizure events on two different datasets (CHB-MIT and PEDESITE, respectively), with only four EEG channels. A three-window majority voting-based smoothing scheme combined with the SSWCE loss achieves 3x reduction of false positives to 1.18 FP/h. EpiDeNet is well suited for implementation on low-power embedded platforms, and we evaluate its performance on two ARM Cortex-based platforms (M4F/M7) and two parallel ultra-low power (PULP) systems (GAP8, GAP9). The most efficient implementation (GAP9) achieves an energy efficiency of 40 GMAC/s/W, with an energy consumption per inference of only 0.051 mJ at high performance (726.46 MMAC/s), outperforming the best ARM Cortex-based solutions by approximately 160x in energy efficiency. The EpiDeNet-SSWCE method demonstrates effective and accurate seizure detection performance on heavily imbalanced datasets, while being suited for implementation on energy-constrained platforms., Comment: 5 pages, 4 tables, 1 figure, Accepted at BioCAS 2023

Published
2023

5. BioGAP: a 10-Core FP-capable Ultra-Low Power IoT Processor, with Medical-Grade AFE and BLE Connectivity for Wearable Biosignal Processing

Author

Frey, Sebastian, Guermandi, Marco, Benatti, Simone, Kartsch, Victor, Cossettini, Andrea, and Benini, Luca

Subjects
Electrical Engineering and Systems Science - Systems and Control, Computer Science - Human-Computer Interaction
Abstract

Wearable biosignal processing applications are driving significant progress toward miniaturized, energy-efficient Internet-of-Things solutions for both clinical and consumer applications. However, scaling toward high-density multi-channel front-ends is only feasible by performing data processing and machine Learning (ML) near-sensor through energy-efficient edge processing. To tackle these challenges, we introduce BioGAP, a novel, compact, modular, and lightweight (6g) medical-grade biosignal acquisition and processing platform powered by GAP9, a ten-core ultra-low-power SoC designed for efficient multi-precision (from FP to aggressively quantized integer) processing, as required for advanced ML and DSP. BioGAPs form factor is 16x21x14 mm$^3$ and comprises two stacked PCBs: a baseboard integrating the GAP9 SoC, a wireless Bluetooth Low Energy (BLE) capable SoC, a power management circuit, and an accelerometer; and a shield including an analog front-end (AFE) for ExG acquisition. Finally, the system also includes a flexibly placeable photoplethysmogram (PPG) PCB with a size of 9x7x3 mm$^3$ and a rechargeable battery ($\phi$ 12x5 mm$^2$). We demonstrate BioGAP on a Steady State Visually Evoked Potential (SSVEP)-based Brain-Computer Interface (BCI) application. We achieve 3.6 uJ/sample in streaming and 2.2 uJ/sample in onboard processing mode, thanks to an efficiency on the FFT computation task of 16.7 Mflops/s/mW with wireless bandwidth reduction of 97%, within a power budget of just 18.2 mW allowing for an operation time of 15 h., Comment: 7 pages, 9 figures, 1 table, accepted for IEEE COINS 2023

Published
2023

8. Echoes: a 200 GOPS/W Frequency Domain SoC with FFT Processor and I2S DSP for Flexible Data Acquisition from Microphone Arrays

Author

Sinigaglia, Mattia, Bertaccini, Luca, Valente, Luca, Garofalo, Angelo, Benatti, Simone, Benini, Luca, Conti, Francesco, and Rossi, Davide

Subjects
Computer Science - Hardware Architecture
Abstract

Emerging applications in the IoT domain require ultra-low-power and high-performance end-nodes to deal with complex near-sensor-data analytics. Domains such as audio, radar, and Structural Health Monitoring require many computations to be performed in the frequency domain rather than in the time domain. We present ECHOES, a System-On-a-Chip (SoC) composed of a RISC-V core enhanced with fixed and floating-point digital signal processing (DSP) extensions and a Fast-Fourier Transform (FFT) hardware accelerator targeting emerging frequency-domain application. The proposed SoC features an autonomous I/O engine supporting a wide set of peripherals, including Ultra-Low-Power radars, MEMS, and digital microphones over I2S protocol with full-duplex Time Division Multiplexing DSP mode, making ECHOES the first open-source SoC which offers this functionality enabling simultaneous communication with up to 16 I/Os devices. ECHOES, fabricated with 65nm CMOS technology, reaches a peak performance of 0.16 GFLOPS and a peak energy efficiency of 9.68 GFLOPS/W on a wide range of floating and fixed-point general-purpose DSP kernels. The FFT accelerator achieves performance up to 10.16 GOPS with an efficiency of 199.8 GOPS/W, improving performance and efficiency by up to 41.1x and 11.2x, respectively, over its software implementation of this critical task for frequency domain processing.

Published
2023

9. Long-term stable Electromyography classification using Canonical Correlation Analysis

Author

Donati, Elisa, Benatti, Simone, Ceolini, Enea, and Indiveri, Giacomo

Subjects
Computer Science - Machine Learning, Computer Science - Human-Computer Interaction, Electrical Engineering and Systems Science - Signal Processing, Statistics - Applications
Abstract

Discrimination of hand gestures based on the decoding of surface electromyography (sEMG) signals is a well-establish approach for controlling prosthetic devices and for Human-Machine Interfaces (HMI). However, despite the promising results achieved by this approach in well-controlled experimental conditions, its deployment in long-term real-world application scenarios is still hindered by several challenges. One of the most critical challenges is maintaining high EMG data classification performance across multiple days without retraining the decoding system. The drop in performance is mostly due to the high EMG variability caused by electrodes shift, muscle artifacts, fatigue, user adaptation, or skin-electrode interfacing issues. Here we propose a novel statistical method based on canonical correlation analysis (CCA) that stabilizes EMG classification performance across multiple days for long-term control of prosthetic devices. We show how CCA can dramatically decrease the performance drop of standard classifiers observed across days, by maximizing the correlation among multiple-day acquisition data sets. Our results show how the performance of a classifier trained on EMG data acquired only of the first day of the experiment maintains 90% relative accuracy across multiple days, compensating for the EMG data variability that occurs over long-term periods, using the CCA transformation on data obtained from a small number of gestures. This approach eliminates the need for large data sets and multiple or periodic training sessions, which currently hamper the usability of conventional pattern recognition based approaches

Published
2023

10. Energy-Efficient Tree-Based EEG Artifact Detection

Author

Ingolfsson, Thorir Mar, Cossettini, Andrea, Benatti, Simone, and Benini, Luca

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Machine Learning
Abstract

In the context of epilepsy monitoring, EEG artifacts are often mistaken for seizures due to their morphological similarity in both amplitude and frequency, making seizure detection systems susceptible to higher false alarm rates. In this work we present the implementation of an artifact detection algorithm based on a minimal number of EEG channels on a parallel ultra-low-power (PULP) embedded platform. The analyses are based on the TUH EEG Artifact Corpus dataset and focus on the temporal electrodes. First, we extract optimal feature models in the frequency domain using an automated machine learning framework, achieving a 93.95% accuracy, with a 0.838 F1 score for a 4 temporal EEG channel setup. The achieved accuracy levels surpass state-of-the-art by nearly 20%. Then, these algorithms are parallelized and optimized for a PULP platform, achieving a 5.21 times improvement of energy-efficient compared to state-of-the-art low-power implementations of artifact detection frameworks. Combining this model with a low-power seizure detection algorithm would allow for 300h of continuous monitoring on a 300 mAh battery in a wearable form factor and power budget. These results pave the way for implementing affordable, wearable, long-term epilepsy monitoring solutions with low false-positive rates and high sensitivity, meeting both patients' and caregivers' requirements., Comment: 6 pages, 3 figures, 2 tables

Published
2022

11. Robust and Energy-efficient PPG-based Heart-Rate Monitoring

Author

Risso, Matteo, Burrello, Alessio, Pagliari, Daniele Jahier, Benatti, Simone, Macii, Enrico, Benini, Luca, and Poncino, Massimo

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Machine Learning
Abstract

A wrist-worn PPG sensor coupled with a lightweight algorithm can run on a MCU to enable non-invasive and comfortable monitoring, but ensuring robust PPG-based heart-rate monitoring in the presence of motion artifacts is still an open challenge. Recent state-of-the-art algorithms combine PPG and inertial signals to mitigate the effect of motion artifacts. However, these approaches suffer from limited generality. Moreover, their deployment on MCU-based edge nodes has not been investigated. In this work, we tackle both the aforementioned problems by proposing the use of hardware-friendly Temporal Convolutional Networks (TCN) for PPG-based heart estimation. Starting from a single "seed" TCN, we leverage an automatic Neural Architecture Search (NAS) approach to derive a rich family of models. Among them, we obtain a TCN that outperforms the previous state-of-the-art on the largest PPG dataset available (PPGDalia), achieving a Mean Absolute Error (MAE) of just 3.84 Beats Per Minute (BPM). Furthermore, we tested also a set of smaller yet still accurate (MAE of 5.64 - 6.29 BPM) networks that can be deployed on a commercial MCU (STM32L4) which require as few as 5k parameters and reach a latency of 17.1 ms consuming just 0.21 mJ per inference.

Published
2022
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12. Q-PPG: Energy-Efficient PPG-based Heart Rate Monitoring on Wearable Devices

Author

Burrello, Alessio, Pagliari, Daniele Jahier, Risso, Matteo, Benatti, Simone, Macii, Enrico, Benini, Luca, and Poncino, Massimo

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Hearth Rate (HR) monitoring is increasingly performed in wrist-worn devices using low-cost photoplethysmography (PPG) sensors. However, Motion Artifacts (MAs) caused by movements of the subject's arm affect the performance of PPG-based HR tracking. This is typically addressed coupling the PPG signal with acceleration measurements from an inertial sensor. Unfortunately, most standard approaches of this kind rely on hand-tuned parameters, which impair their generalization capabilities and their applicability to real data in the field. In contrast, methods based on deep learning, despite their better generalization, are considered to be too complex to deploy on wearable devices. In this work, we tackle these limitations, proposing a design space exploration methodology to automatically generate a rich family of deep Temporal Convolutional Networks (TCNs) for HR monitoring, all derived from a single "seed" model. Our flow involves a cascade of two Neural Architecture Search (NAS) tools and a hardware-friendly quantizer, whose combination yields both highly accurate and extremely lightweight models. When tested on the PPG-Dalia dataset, our most accurate model sets a new state-of-the-art in Mean Absolute Error. Furthermore, we deploy our TCNs on an embedded platform featuring a STM32WB55 microcontroller, demonstrating their suitability for real-time execution. Our most accurate quantized network achieves 4.41 Beats Per Minute (BPM) of Mean Absolute Error (MAE), with an energy consumption of 47.65 mJ and a memory footprint of 412 kB. At the same time, the smallest network that obtains a MAE < 8 BPM, among those generated by our flow, has a memory footprint of 1.9 kB and consumes just 1.79 mJ per inference.

Published
2022

13. Bioformers: Embedding Transformers for Ultra-Low Power sEMG-based Gesture Recognition

Author

Burrello, Alessio, Morghet, Francesco Bianco, Scherer, Moritz, Benatti, Simone, Benini, Luca, Macii, Enrico, Poncino, Massimo, and Pagliari, Daniele Jahier

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Machine Learning
Abstract

Human-machine interaction is gaining traction in rehabilitation tasks, such as controlling prosthetic hands or robotic arms. Gesture recognition exploiting surface electromyographic (sEMG) signals is one of the most promising approaches, given that sEMG signal acquisition is non-invasive and is directly related to muscle contraction. However, the analysis of these signals still presents many challenges since similar gestures result in similar muscle contractions. Thus the resulting signal shapes are almost identical, leading to low classification accuracy. To tackle this challenge, complex neural networks are employed, which require large memory footprints, consume relatively high energy and limit the maximum battery life of devices used for classification. This work addresses this problem with the introduction of the Bioformers. This new family of ultra-small attention-based architectures approaches state-of-the-art performance while reducing the number of parameters and operations of 4.9X. Additionally, by introducing a new inter-subjects pre-training, we improve the accuracy of our best Bioformer by 3.39%, matching state-of-the-art accuracy without any additional inference cost. Deploying our best performing Bioformer on a Parallel, Ultra-Low Power (PULP) microcontroller unit (MCU), the GreenWaves GAP8, we achieve an inference latency and energy of 2.72 ms and 0.14 mJ, respectively, 8.0X lower than the previous state-of-the-art neural network, while occupying just 94.2 kB of memory.

Published
2022

14. Embedding Temporal Convolutional Networks for Energy-Efficient PPG-Based Heart Rate Monitoring

Author

Burrello, Alessio, Pagliari, Daniele Jahier, Rapa, Pierangelo Maria, Semilia, Matilde, Risso, Matteo, Polonelli, Tommaso, Poncino, Massimo, Benini, Luca, and Benatti, Simone

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Human-Computer Interaction, Computer Science - Machine Learning
Abstract

Photoplethysmography (PPG) sensors allow for non-invasive and comfortable heart-rate (HR) monitoring, suitable for compact wrist-worn devices. Unfortunately, Motion Artifacts (MAs) severely impact the monitoring accuracy, causing high variability in the skin-to-sensor interface. Several data fusion techniques have been introduced to cope with this problem, based on combining PPG signals with inertial sensor data. Until know, both commercial and reasearch solutions are computationally efficient but not very robust, or strongly dependent on hand-tuned parameters, which leads to poor generalization performance. % In this work, we tackle these limitations by proposing a computationally lightweight yet robust deep learning-based approach for PPG-based HR estimation. Specifically, we derive a diverse set of Temporal Convolutional Networks (TCN) for HR estimation, leveraging Neural Architecture Search (NAS). Moreover, we also introduce ActPPG, an adaptive algorithm that selects among multiple HR estimators depending on the amount of MAs, to improve energy efficiency. We validate our approaches on two benchmark datasets, achieving as low as 3.84 Beats per Minute (BPM) of Mean Absolute Error (MAE) on PPGDalia, which outperforms the previous state-of-the-art. Moreover, we deploy our models on a low-power commercial microcontroller (STM32L4), obtaining a rich set of Pareto optimal solutions in the complexity vs. accuracy space.

Published
2022

15. A Fully-Integrated 5mW, 0.8Gbps Energy-Efficient Chip-to-Chip Data Link for Ultra-Low-Power IoT End-Nodes in 65-nm CMOS

Author

Okuhara, Hayate, Elnaqib, Ahmed, Dazzi, Martino, Palestri, Pierpaolo, Benatti, Simone, Benini, Luca, and Rossi, Davide

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Hardware Architecture
Abstract

The increasing complexity of Internet-of-Things (IoT) applications and near-sensor processing algorithms is pushing the computational power of low-power, battery-operated end-node systems. This trend also reveals growing demands for high-speed and energy-efficient inter-chip communications to manage the increasing amount of data coming from off-chip sensors and memories. While traditional micro-controller interfaces such as SPIs cannot cope with tight energy and large bandwidth requirements, low-voltage swing transceivers can tackle this challenge thanks to their capability to achieve several Gbps of the communication speed at milliwatt power levels. However, recent research on high-speed serial links focused on high-performance systems, with a power consumption significantly larger than the one of low-power IoT end-nodes, or on stand-alone designs not integrated at a system level. This paper presents a low-swing transceiver for the energy-efficient and low power chip-to-chip communication fully integrated within an IoT end-node System-on-Chip, fabricated in CMOS 65nm technology. The transceiver can be easily controlled via a software interface; thus, we can consider realistic scenarios for the data communication, which cannot be assessed in stand-alone prototypes. Chip measurements show that the transceiver achieves 8.46x higher energy efficiency at 15.9x higher performance than a traditional microcontroller interface such as a single-SPI.

Published
2021
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16. Monoclonal antibodies against SARS-CoV-2 to prevent COVID-19 worsening in a large multicenter cohort

Author

Soria, Alessandro, Graziano, Francesca, Ghilardi, Giulia, Lapadula, Giuseppe, Gasperina, Daniela Dalla, Benatti, Simone Vasilij, Quiros-Roldan, Eugenia, Milesi, Maurizio, Bai, Francesca, Merli, Marco, Minisci, Davide, Franzetti, Marco, Asperges, Erika, Chiabrando, Filippo, Pocaterra, Daria, Pandolfo, Alessandro, Zanini, Fabio, Lombardi, Domenico, Cappelletti, Anna, Rugova, Alban, Borghesi, Maria Lucia, Squillace, Nicola, Pusterla, Luigi, Piconi, Stefania, Morelli, Paola, Querini, Patrizia Rovere, Bruno, Raffaele, Rusconi, Stefano, Casari, Salvatore, Bandera, Alessandra, Franzetti, Fabio, Travi, Giovanna, D'Arminio Monforte, Antonella, Marchetti, Giulia, Pan, Angelo, Castelli, Francesco, Rizzi, Marco, Dentali, Francesco, Mallardo, Maria, Rossi, Emanuela, Valsecchi, Maria Grazia, Galimberti, Stefania, and Bonfanti, Paolo

Published
2024
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17. Towards Long-term Non-invasive Monitoring for Epilepsy via Wearable EEG Devices

Author

Ingolfsson, Thorir Mar, Cossettini, Andrea, Wang, Xiaying, Tabanelli, Enrico, Tagliavini, Giuseppe, Ryvlin, Philippe, Benini, Luca, and Benatti, Simone

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Human-Computer Interaction, Computer Science - Machine Learning
Abstract

We present the implementation of seizure detection algorithms based on a minimal number of EEG channels on a parallel ultra-low-power embedded platform. The analyses are based on the CHB-MIT dataset, and include explorations of different classification approaches (Support Vector Machines, Random Forest, Extra Trees, AdaBoost) and different pre/post-processing techniques to maximize sensitivity while guaranteeing no false alarms. We analyze global and subject-specific approaches, considering all 23-electrodes or only 4 temporal channels. For 8s window size and subject-specific approach, we report zero false positives and 100% sensitivity. These algorithms are parallelized and optimized for a parallel ultra-low power (PULP) platform, enabling 300h of continuous monitoring on a 300 mAh battery, in a wearable form factor and power budget. These results pave the way for the implementation of affordable, wearable, long-term epilepsy monitoring solutions with low false-positive rates and high sensitivity, meeting both patient and caregiver requirements., Comment: 4 pages, 3 figures, 2 tables, preprint

Published
2021

18. Exploiting Blood Volume Pulse and Skin Conductance for Driver Drowsiness Detection

Author

Poli, Angelica, Amidei, Andrea, Benatti, Simone, Iadarola, Grazia, Tramarin, Federico, Rovati, Luigi, Pavan, Paolo, Spinsante, Susanna, Akan, Ozgur, Editorial Board Member, Bellavista, Paolo, Editorial Board Member, Cao, Jiannong, Editorial Board Member, Coulson, Geoffrey, Editorial Board Member, Dressler, Falko, Editorial Board Member, Ferrari, Domenico, Editorial Board Member, Gerla, Mario, Editorial Board Member, Kobayashi, Hisashi, Editorial Board Member, Palazzo, Sergio, Editorial Board Member, Sahni, Sartaj, Editorial Board Member, Shen, Xuemin, Editorial Board Member, Stan, Mircea, Editorial Board Member, Jia, Xiaohua, Editorial Board Member, Zomaya, Albert Y., Editorial Board Member, Spinsante, Susanna, editor, Iadarola, Grazia, editor, Paglialonga, Alessia, editor, and Tramarin, Federico, editor

Published
2023
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19. Motor-Unit Ordering of Blindly-Separated Surface-EMG Signals for Gesture Recognition

Author

Orlandi, Mattia, Zanghieri, Marcello, Schiavone, Davide, Donati, Elisa, Conti, Francesco, Benatti, Simone, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Valle, Maurizio, editor, Lehmhus, Dirk, editor, Gianoglio, Christian, editor, Ragusa, Edoardo, editor, Seminara, Lucia, editor, Bosse, Stefan, editor, Ibrahim, Ali, editor, and Thoben, Klaus-Dieter, editor

Published
2023
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20. An Optimized Heart Rate Detection System Based on Low-Power Microcontroller Platforms for Biosignal Processing

Author

Mazzoni, Benedetta, Tagliavini, Giuseppe, Benini, Luca, Benatti, Simone, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Valle, Maurizio, editor, Lehmhus, Dirk, editor, Gianoglio, Christian, editor, Ragusa, Edoardo, editor, Seminara, Lucia, editor, Bosse, Stefan, editor, Ibrahim, Ali, editor, and Thoben, Klaus-Dieter, editor

Published
2023
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21. A transprecision floating-point cluster for efficient near-sensor data analytics

Author

Montagna, Fabio, Mach, Stefan, Benatti, Simone, Garofalo, Angelo, Ottavi, Gianmarco, Benini, Luca, Rossi, Davide, and Tagliavini, Giuseppe

Subjects
Computer Science - Distributed, Parallel, and Cluster Computing, Computer Science - Hardware Architecture
Abstract

Recent applications in the domain of near-sensor computing require the adoption of floating-point arithmetic to reconcile high precision results with a wide dynamic range. In this paper, we propose a multi-core computing cluster that leverages the fined-grained tunable principles of transprecision computing to provide support to near-sensor applications at a minimum power budget. Our design - based on the open-source RISC-V architecture - combines parallelization and sub-word vectorization with near-threshold operation, leading to a highly scalable and versatile system. We perform an exhaustive exploration of the design space of the transprecision cluster on a cycle-accurate FPGA emulator, with the aim to identify the most efficient configurations in terms of performance, energy efficiency, and area efficiency. We also provide a full-fledged software stack support, including a parallel runtime and a compilation toolchain, to enable the development of end-to-end applications. We perform an experimental assessment of our design on a set of benchmarks representative of the near-sensor processing domain, complementing the timing results with a post place-&-route analysis of the power consumption. Finally, a comparison with the state-of-the-art shows that our solution outperforms the competitors in energy efficiency, reaching a peak of 97 Gflop/s/W on single-precision scalars and 162 Gflop/s/W on half-precision vectors.

Published
2020
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22. Analysis of Contraction Effort Level in EMG-Based Gesture Recognition Using Hyperdimensional Computing

Author

Moin, Ali, Zhou, Andy, Benatti, Simone, Rahimi, Abbas, Benini, Luca, and Rabaey, Jan M.

Subjects
Computer Science - Human-Computer Interaction, Computer Science - Machine Learning, Electrical Engineering and Systems Science - Signal Processing
Abstract

Varying contraction levels of muscles is a big challenge in electromyography-based gesture recognition. Some use cases require the classifier to be robust against varying force changes, while others demand to distinguish between different effort levels of performing the same gesture. We use brain-inspired hyperdimensional computing paradigm to build classification models that are both robust to these variations and able to recognize multiple contraction levels. Experimental results on 5 subjects performing 9 gestures with 3 effort levels show up to 39.17% accuracy drop when training and testing across different effort levels, with up to 30.35% recovery after applying our algorithm., Comment: Published as a conference paper at the IEEE BioCAS 2019

Published
2019

23. ControlPULP: A RISC-V Power Controller for HPC Processors with Parallel Control-Law Computation Acceleration

Author

Ottaviano, Alessandro, Balas, Robert, Bambini, Giovanni, Bonfanti, Corrado, Benatti, Simone, Rossi, Davide, Benini, Luca, Bartolini, Andrea, Goos, Gerhard, Founding Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Orailoglu, Alex, editor, Reichenbach, Marc, editor, and Jung, Matthias, editor

Published
2022
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26. Reducing False Alarms in Wearable Seizure Detection With EEGformer: A Compact Transformer Model for MCUs

Author

Busia, Paola, primary, Cossettini, Andrea, additional, Ingolfsson, Thorir Mar, additional, Benatti, Simone, additional, Burrello, Alessio, additional, Jung, Victor J. B., additional, Scherer, Moritz, additional, Scrugli, Matteo A., additional, Bernini, Adriano, additional, Ducouret, Pauline, additional, Ryvlin, Philippe, additional, Meloni, Paolo, additional, and Benini, Luca, additional

Published
2024
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27. PULP-HD: Accelerating Brain-Inspired High-Dimensional Computing on a Parallel Ultra-Low Power Platform

Author

Montagna, Fabio, Rahimi, Abbas, Benatti, Simone, Rossi, Davide, and Benini, Luca

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

Computing with high-dimensional (HD) vectors, also referred to as $\textit{hypervectors}$, is a brain-inspired alternative to computing with scalars. Key properties of HD computing include a well-defined set of arithmetic operations on hypervectors, generality, scalability, robustness, fast learning, and ubiquitous parallel operations. HD computing is about manipulating and comparing large patterns-binary hypervectors with 10,000 dimensions-making its efficient realization on minimalistic ultra-low-power platforms challenging. This paper describes HD computing's acceleration and its optimization of memory accesses and operations on a silicon prototype of the PULPv3 4-core platform (1.5mm$^2$, 2mW), surpassing the state-of-the-art classification accuracy (on average 92.4%) with simultaneous 3.7$\times$ end-to-end speed-up and 2$\times$ energy saving compared to its single-core execution. We further explore the scalability of our accelerator by increasing the number of inputs and classification window on a new generation of the PULP architecture featuring bit-manipulation instruction extensions and larger number of 8 cores. These together enable a near ideal speed-up of 18.4$\times$ compared to the single-core PULPv3.

Published
2018

28. An EMG Gesture Recognition System with Flexible High-Density Sensors and Brain-Inspired High-Dimensional Classifier

Author

Moin, Ali, Zhou, Andy, Rahimi, Abbas, Benatti, Simone, Menon, Alisha, Tamakloe, Senam, Ting, Jonathan, Yamamoto, Natasha, Khan, Yasser, Burghardt, Fred, Benini, Luca, Arias, Ana C., and Rabaey, Jan M.

Subjects
Computer Science - Human-Computer Interaction, Computer Science - Learning, Electrical Engineering and Systems Science - Signal Processing
Abstract

EMG-based gesture recognition shows promise for human-machine interaction. Systems are often afflicted by signal and electrode variability which degrades performance over time. We present an end-to-end system combating this variability using a large-area, high-density sensor array and a robust classification algorithm. EMG electrodes are fabricated on a flexible substrate and interfaced to a custom wireless device for 64-channel signal acquisition and streaming. We use brain-inspired high-dimensional (HD) computing for processing EMG features in one-shot learning. The HD algorithm is tolerant to noise and electrode misplacement and can quickly learn from few gestures without gradient descent or back-propagation. We achieve an average classification accuracy of 96.64% for five gestures, with only 7% degradation when training and testing across different days. Our system maintains this accuracy when trained with only three trials of gestures; it also demonstrates comparable accuracy with the state-of-the-art when trained with one trial.

Published
2018

32. Splenic trauma: WSES classification and guidelines for adult and pediatric patients

Author

Coccolini, Federico, Montori, Giulia, Catena, Fausto, Kluger, Yoram, Biffl, Walter, Moore, Ernest E, Reva, Viktor, Bing, Camilla, Bala, Miklosh, Fugazzola, Paola, Bahouth, Hany, Marzi, Ingo, Velmahos, George, Ivatury, Rao, Soreide, Kjetil, Horer, Tal, ten Broek, Richard, Pereira, Bruno M, Fraga, Gustavo P, Inaba, Kenji, Kashuk, Joseph, Parry, Neil, Masiakos, Peter T, Mylonas, Konstantinos S, Kirkpatrick, Andrew, Abu-Zidan, Fikri, Gomes, Carlos Augusto, Benatti, Simone Vasilij, Naidoo, Noel, Salvetti, Francesco, Maccatrozzo, Stefano, Agnoletti, Vanni, Gamberini, Emiliano, Solaini, Leonardo, Costanzo, Antonio, Celotti, Andrea, Tomasoni, Matteo, Khokha, Vladimir, Arvieux, Catherine, Napolitano, Lena, Handolin, Lauri, Pisano, Michele, Magnone, Stefano, Spain, David A, de Moya, Marc, Davis, Kimberly A, De Angelis, Nicola, Leppaniemi, Ari, Ferrada, Paula, Latifi, Rifat, Navarro, David Costa, Otomo, Yashuiro, Coimbra, Raul, Maier, Ronald V, Moore, Frederick, Rizoli, Sandro, Sakakushev, Boris, Galante, Joseph M, Chiara, Osvaldo, Cimbanassi, Stefania, Mefire, Alain Chichom, Weber, Dieter, Ceresoli, Marco, Peitzman, Andrew B, Wehlie, Liban, Sartelli, Massimo, Di Saverio, Salomone, and Ansaloni, Luca

Subjects
Physical Injury - Accidents and Adverse Effects, Childhood Injury, Emergency Care, Patient Safety, Pediatric, Hematology, Injuries and accidents, Abdominal Injuries, Adult, Conservative Treatment, Guidelines as Topic, Hemodynamics, Humans, Spleen, Wounds and Injuries, Trauma, Classification, Guidelines, Embolization, Surgery, Non-operative, Conservative
Abstract

Spleen injuries are among the most frequent trauma-related injuries. At present, they are classified according to the anatomy of the injury. The optimal treatment strategy, however, should keep into consideration the hemodynamic status, the anatomic derangement, and the associated injuries. The management of splenic trauma patients aims to restore the homeostasis and the normal physiopathology especially considering the modern tools for bleeding management. Thus, the management of splenic trauma should be ultimately multidisciplinary and based on the physiology of the patient, the anatomy of the injury, and the associated lesions. Lastly, as the management of adults and children must be different, children should always be treated in dedicated pediatric trauma centers. In fact, the vast majority of pediatric patients with blunt splenic trauma can be managed non-operatively. This paper presents the World Society of Emergency Surgery (WSES) classification of splenic trauma and the management guidelines.

Published
2017

37. Socio-economic conditions affect health-related quality of life, during recovery from acute SARS-CoV-2 infection : Results from the VASCO study (VAriabili Socioeconomiche e COVID-19), on the 'Surviving-COVID' cohort, from Bergamo (Italy)

Author

Benatti, S, Venturelli, S, Buzzetti, R, Binda, F, Belotti, L, Soavi, L, Biffi, A, Spada, M, Casati, M, Rizzi, M, Benatti, Simone Vasilij, Venturelli, Serena, Buzzetti, Roberto, Binda, Francesca, Belotti, Luca, Soavi, Laura, Biffi, Ave Maria, Spada, Maria Simonetta, Casati, Monica, Rizzi, Marco, Benatti, S, Venturelli, S, Buzzetti, R, Binda, F, Belotti, L, Soavi, L, Biffi, A, Spada, M, Casati, M, Rizzi, M, Benatti, Simone Vasilij, Venturelli, Serena, Buzzetti, Roberto, Binda, Francesca, Belotti, Luca, Soavi, Laura, Biffi, Ave Maria, Spada, Maria Simonetta, Casati, Monica, and Rizzi, Marco

Abstract

Background: Recovery from acute COVID-19 may be slow and incomplete: cases of Post-Acute Sequelae of COVID (PASC) are counted in millions, worldwide. We aimed to explore if and how the pre-existing Socio-economic-status (SES) influences such recovery. Methods: We analyzed a database of 1536 consecutive patients from the first wave of COVID-19 in Italy (February-September 2020), previously admitted to our referral hospital, and followed-up in a dedicated multidisciplinary intervention. We excluded those seen earlier than 12 weeks (the conventional limit for a possible PASC syndrome), and those reporting a serious complication from the acute phase (possibly accounting for symptoms persistence). We studied whether the exposition to disadvantaged SES (estimated through the Italian Institute of Statistics's model - ISTAT 2017) was affecting recovery outcomes, that is: symptoms (composite endpoint, i.e. at least one among: dyspnea, fatigue, myalgia, chest pain or palpitations); Health-Related-Quality-of-Life (HRQoL, as by SF-36 scale); post-traumatic-stress-disorder (as by IES-R scale); and lung structural damage (as by impaired CO diffusion, DLCO). Results: Eight-hundred and twenty-five patients were included in the analysis (median age 59 years; IQR: 50-69 years, 60.2% men), of which 499 (60.5%) were previously admitted to hospital and 27 (3.3%) to Intensive-Care Unit (ICU). Those still complaining of symptoms at follow-up were 337 (40.9%; 95%CI 37.5-42.2%), and 256 had a possible Post-Traumatic Stress Disorder (PTSD) (31%, 95%CI 28.7-35.1%). DLCO was reduced in 147 (19.6%, 95%CI 17.0-22.7%). In a multivariable model, disadvantaged SES was associated with a lower HRQoL, especially for items exploring physical health (Limitations in physical activities: OR = 0.65; 95%CI = 0.47 to 0.89; p = 0.008; AUC = 0.74) and Bodily pain (OR = 0.57; 95%CI = 0.40 to 0.82; p = 0.002; AUC = 0.74). We did not observe any association between SES and the other outcomes. Conclusions: Recover

Published
2024

38. Monoclonal antibodies against SARS-CoV-2 to prevent COVID-19 worsening in a large multicenter cohort

Author

Soria, A, Graziano, F, Ghilardi, G, Lapadula, G, Gasperina, D, Benatti, S, Quiros-Roldan, E, Milesi, M, Bai, F, Merli, M, Minisci, D, Franzetti, M, Asperges, E, Chiabrando, F, Pocaterra, D, Pandolfo, A, Zanini, F, Lombardi, D, Cappelletti, A, Rugova, A, Borghesi, M, Squillace, N, Pusterla, L, Piconi, S, Morelli, P, Querini, P, Bruno, R, Rusconi, S, Casari, S, Bandera, A, Franzetti, F, Travi, G, D'Arminio Monforte, A, Marchetti, G, Pan, A, Castelli, F, Rizzi, M, Dentali, F, Mallardo, M, Rossi, E, Valsecchi, M, Galimberti, S, Bonfanti, P, Soria, Alessandro, Graziano, Francesca, Ghilardi, Giulia, Lapadula, Giuseppe, Gasperina, Daniela Dalla, Benatti, Simone Vasilij, Quiros-Roldan, Eugenia, Milesi, Maurizio, Bai, Francesca, Merli, Marco, Minisci, Davide, Franzetti, Marco, Asperges, Erika, Chiabrando, Filippo, Pocaterra, Daria, Pandolfo, Alessandro, Zanini, Fabio, Lombardi, Domenico, Cappelletti, Anna, Rugova, Alban, Borghesi, Maria Lucia, Squillace, Nicola, Pusterla, Luigi, Piconi, Stefania, Morelli, Paola, Querini, Patrizia Rovere, Bruno, Raffaele, Rusconi, Stefano, Casari, Salvatore, Bandera, Alessandra, Franzetti, Fabio, Travi, Giovanna, D'Arminio Monforte, Antonella, Marchetti, Giulia, Pan, Angelo, Castelli, Francesco, Rizzi, Marco, Dentali, Francesco, Mallardo, Maria, Rossi, Emanuela, Valsecchi, Maria Grazia, Galimberti, Stefania, Bonfanti, Paolo, Soria, A, Graziano, F, Ghilardi, G, Lapadula, G, Gasperina, D, Benatti, S, Quiros-Roldan, E, Milesi, M, Bai, F, Merli, M, Minisci, D, Franzetti, M, Asperges, E, Chiabrando, F, Pocaterra, D, Pandolfo, A, Zanini, F, Lombardi, D, Cappelletti, A, Rugova, A, Borghesi, M, Squillace, N, Pusterla, L, Piconi, S, Morelli, P, Querini, P, Bruno, R, Rusconi, S, Casari, S, Bandera, A, Franzetti, F, Travi, G, D'Arminio Monforte, A, Marchetti, G, Pan, A, Castelli, F, Rizzi, M, Dentali, F, Mallardo, M, Rossi, E, Valsecchi, M, Galimberti, S, Bonfanti, P, Soria, Alessandro, Graziano, Francesca, Ghilardi, Giulia, Lapadula, Giuseppe, Gasperina, Daniela Dalla, Benatti, Simone Vasilij, Quiros-Roldan, Eugenia, Milesi, Maurizio, Bai, Francesca, Merli, Marco, Minisci, Davide, Franzetti, Marco, Asperges, Erika, Chiabrando, Filippo, Pocaterra, Daria, Pandolfo, Alessandro, Zanini, Fabio, Lombardi, Domenico, Cappelletti, Anna, Rugova, Alban, Borghesi, Maria Lucia, Squillace, Nicola, Pusterla, Luigi, Piconi, Stefania, Morelli, Paola, Querini, Patrizia Rovere, Bruno, Raffaele, Rusconi, Stefano, Casari, Salvatore, Bandera, Alessandra, Franzetti, Fabio, Travi, Giovanna, D'Arminio Monforte, Antonella, Marchetti, Giulia, Pan, Angelo, Castelli, Francesco, Rizzi, Marco, Dentali, Francesco, Mallardo, Maria, Rossi, Emanuela, Valsecchi, Maria Grazia, Galimberti, Stefania, and Bonfanti, Paolo

Abstract

Objective Monoclonal antibodies (mAbs) against Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) reduced Coronavirus Disease 2019 (COVID-19) hospitalizations in people at risk of clinical worsening. Real-world descriptions are limited. Methods CONDIVIDIAMO, a two-year multicenter observational study, consecutively enrolled SARS-CoV-2 outpatients with ≥1 risk factor for COVID-19 progression receiving mAbs. Demographic data, underlying medical condition, type of mAbs combination received, duration of symptoms before mAbs administration, COVID-19 vaccination history, were collected upon enrolment and centrally recorded. Data on outcomes (hospitalizations, reasons of hospitalization, deaths) were prospectively collected. The primary endpoint was the rate of hospitalization or death in a 28-day follow-up, whichever occurred first; subjects were censored at the day of last follow-up or up to 28 days. The Kaplan-Meier method was used to estimate the incidence rate curve in time. The Cox regression model was used to assess potential risk factors for unfavorable outcome. Results were shown as hazard ratio (HR) along with the corresponding 95 % Confidence Interval (95%CI). Results Among 1534 subjects (median [interquartile range, IQR] age 66.5 [52.4–74.9] years, 693 [45.2 %] women), 632 (41.2 %) received bamlanivimab ± etesevimab, 209 (13.6 %) casirivimab/imdevimab, 586 (38.2 %) sotrovimab, 107 (7.0 %) tixagevimab/cilgavimab. After 28-day follow-up, 87/1534 (5.6 %, 95%CI: 4.4%–6.8 %) met the primary outcome (85 hospitalizations, 2 deaths). Hospitalizations for COVID-19 (52, 3.4 %) occurred earlier than for other reasons (33, 2.1 %), after a median (IQR) of 3.5 (1–7) versus 8 (3–15) days (p = 0.006) from mAbs administration. In a multivariable Cox regression model, factors independently associated with increased hospitalization risk were age (hazard ratio [HR] 1.02, 95%CI 1.00–1.03, p = 0.021), immunodeficiency (HR 1.78, 95%CI 1.11–2.85, p = 0.017), pre-Omicron cale

Published
2024

45. A Heterogeneous RISC-V Based SoC for Secure Nano-UAV Navigation

Author

Valente, Luca, primary, Nadalini, Alessandro, additional, Veeran, Asif Hussain Chiralil, additional, Sinigaglia, Mattia, additional, Sá, Bruno, additional, Wistoff, Nils, additional, Tortorella, Yvan, additional, Benatti, Simone, additional, Psiakis, Rafail, additional, Kulmala, Ari, additional, Mohammad, Baker, additional, Pinto, Sandro, additional, Palossi, Daniele, additional, Benini, Luca, additional, and Rossi, Davide, additional

Published
2024
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50. <sc>BrainFuseNet</sc>: Enhancing Wearable Seizure Detection Through EEG-PPG-Accelerometer Sensor Fusion and Efficient Edge Deployment

Author

Ingolfsson, Thorir Mar, Wang, Xiaying, Chakraborty, Upasana, Benatti, Simone, Bernini, Adriano, Ducouret, Pauline, Ryvlin, Philippe, Beniczky, Sandor, Benini, Luca, and Cossettini, Andrea

Abstract

This paper introduces BrainFuseNet, a novel lightweight seizure detection network based on the sensor fusion of electroencephalography (EEG) with photoplethysmography (PPG) and accelerometer (ACC) signals, tailored for low-channel count wearable systems. BrainFuseNet utilizes the Sensitivity-Specificity Weighted Cross-Entropy (SSWCE), an innovative loss function incorporating sensitivity and specificity, to address the challenge of heavily unbalanced datasets. The BrainFuseNet-SSWCE approach successfully detects $93.5\%$ seizure events on the CHB-MIT dataset ($76.34\%$ sample-based sensitivity), for EEG-based classification with only four channels. On the PEDESITE dataset, we demonstrate a sample-based sensitivity and false positive rate of $60.66\%$ and $1.18$ FP/h, respectively, when considering EEG data alone. Additionally, we demonstrate that integrating PPG signals increases the sensitivity to $61.22\%$ (successfully detecting $92\%$ seizure events) while decreasing the number of false positives to $1.0$ FP/h. Finally, when ACC data are also considered, the sensitivity increases to $64.28\%$ (successfully detecting $95\%$ seizure events) and the number of false positives drops to only $0.21$ FP/h for sample-based estimations, with less than one false alarm per day when considering event-based estimations. BrainFuseNet is resource-friendly and well-suited for implementation on low-power embedded platforms, and we evaluate its performance on GAP9, a state-of-the-art parallel ultra-low power (PULP) microcontroller for tiny Machine Learning applications on wearables. The implementation on GAP9 achieves an energy efficiency of $21.43$ GMAC/s/W, with an energy consumption per inference of only $0.11$ mJ at high performance ($412.54$ MMAC/s). The BrainFuseNet-SSWCE method demonstrates effective and accurate seizure detection on heavily imbalanced datasets while achieving state-of-the-art performance in the false positive rate and being well-suited for deployment on energy-constrained edge devices.

Published
2024
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