Developing wearable sensing technologies and unobtrusive devices is paving the way to the design of compelling applications for the next generation of systems for a smart IoT node for Human Machine Interaction (HMI). In this paper we present a smart sensor node for IoT and HMI based on a programmable Parallel Ultra-Low-Power (PULP) platform. We tested the system on a hand gesture recognition application, which is a preferred way of interaction in HMI design. A wearable armband with 8 EMG sensors is controlled by our IoT node, running a machine learning algorithm in real-time, recognizing up to 11 gestures with a power envelope of 11.84 mW. As a result, the proposed approach is capable to 35 hours of continuous operation and 1000 hours in standby. The resulting platform minimizes effectively the power required to run the software application and thus, it allows more power budget for high-quality AFE.

An Energy-Efficient IoT node for HMI applications based on an ultra-low power Multicore Processor / Kartsch, V., Guermandi, M., Benatti, S., Montagna, F., Benini, L.. - (2019), pp. 1-6. (14th IEEE Sensors Applications Symposium, SAS 2019 fra 2019) [10.1109/SAS.2019.8705984].

An Energy-Efficient IoT node for HMI applications based on an ultra-low power Multicore Processor

Benatti S.;
2019

Abstract

Developing wearable sensing technologies and unobtrusive devices is paving the way to the design of compelling applications for the next generation of systems for a smart IoT node for Human Machine Interaction (HMI). In this paper we present a smart sensor node for IoT and HMI based on a programmable Parallel Ultra-Low-Power (PULP) platform. We tested the system on a hand gesture recognition application, which is a preferred way of interaction in HMI design. A wearable armband with 8 EMG sensors is controlled by our IoT node, running a machine learning algorithm in real-time, recognizing up to 11 gestures with a power envelope of 11.84 mW. As a result, the proposed approach is capable to 35 hours of continuous operation and 1000 hours in standby. The resulting platform minimizes effectively the power required to run the software application and thus, it allows more power budget for high-quality AFE.
2019
Inglese
14th IEEE Sensors Applications Symposium, SAS 2019
fra
2019
WOS:000474727000020
2-s2.0-85065927790
SAS 2019 - 2019 IEEE Sensors Applications Symposium, Conference Proceedings
1
6
9781538677131
Institute of Electrical and Electronics Engineers Inc.
STATI UNITI D'AMERICA
345 E 47TH ST, NEW YORK, NY 10017 USA
Internazionale
Contributo
Embedded systems; EMG.; multi-core; PULP; ultra-low power
Kartsch, V.; Guermandi, M.; Benatti, S.; Montagna, F.; Benini, L.
Atti di CONVEGNO::Relazione in Atti di Convegno
273
5
An Energy-Efficient IoT node for HMI applications based on an ultra-low power Multicore Processor / Kartsch, V., Guermandi, M., Benatti, S., Montagna, F., Benini, L.. - (2019), pp. 1-6. (14th IEEE Sensors Applications Symposium, SAS 2019 fra 2019) [10.1109/SAS.2019.8705984].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11380/1255653
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