Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning

Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning

We designed and developed a low-cost mechanical ventilator prototype that meets the government's minimum viable standards. We substituted alternative off-the-shelf food-grade for the medical-grade parts and improvised some components for our prototype. We cleaned the air from the oxygen tanks a...

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Main Authors: Cabacungan, Paul M., Oppus, Carlos M., Cabacungan, Nerissa G., Marmadlo, John Paul A., Santiago, Paul Ryan A., Mercado, Neil Angelo M, Faustino, E. Vincent S., Tangonan, Gregory L
Format: text
Published: Archīum Ateneo 2021
Subjects:
training
vibrations
ventilators
buildings
prototypes
lung
machine learning
COVID-19
breathing device
hospital informatics
critical care
internet of medical things
near cloud
Analytical, Diagnostic and Therapeutic Techniques and Equipment
Artificial Intelligence and Robotics
Computer Sciences
Diagnosis
Health Information Technology
Respiratory Therapy
Online Access:https://archium.ateneo.edu/ecce-faculty-pubs/95
https://ieeexplore.ieee.org/document/9550920
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Institution: Ateneo De Manila University
id ph-ateneo-arc.ecce-faculty-pubs-1094
record_format eprints
spelling ph-ateneo-arc.ecce-faculty-pubs-10942022-01-10T09:17:06Z Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning Cabacungan, Paul M. Oppus, Carlos M. Cabacungan, Nerissa G. Marmadlo, John Paul A. Santiago, Paul Ryan A. Mercado, Neil Angelo M Faustino, E. Vincent S. Tangonan, Gregory L We designed and developed a low-cost mechanical ventilator prototype that meets the government's minimum viable standards. We substituted alternative off-the-shelf food-grade for the medical-grade parts and improvised some components for our prototype. We cleaned the air from the oxygen tanks and compressors before going to the lung test bag. We designed a solar-powered battery system that can run electronic components for a fail-safe operation. We demonstrated how the AIC Near Cloud system can store air flow rate and air pressure data which were generated during the prototype's operation. We used Embedded Machine Learning in sensors and data processing by using flow and pressure sensors to provide accumulated data that can be utilized in training the machine learning software. The patient-ventilator asynchrony detection model was tested using data generated from the emulated ventilator waveform events that mimic the patient-ventilator asynchrony. A different compression pattern was applied to the test lung and results showed the training, validation, and model testing that yielded 98.7%, 99.1%, and 97.18 percent accuracy, respectively. Having demonstrated that the Tiny ML can be trained to detect anomalies from several data points, we realized the feasibility of detecting ventilator patient vibration anomaly, and unusual acoustic signatures, among others, for future works. 2021-01-01T08:00:00Z text https://archium.ateneo.edu/ecce-faculty-pubs/95 https://ieeexplore.ieee.org/document/9550920 Electronics, Computer, and Communications Engineering Faculty Publications Archīum Ateneo training vibrations ventilators buildings prototypes lung machine learning COVID-19 breathing device hospital informatics critical care internet of medical things near cloud Analytical, Diagnostic and Therapeutic Techniques and Equipment Artificial Intelligence and Robotics Computer Sciences Diagnosis Health Information Technology Respiratory Therapy
institution Ateneo De Manila University
building Ateneo De Manila University Library
continent Asia
country Philippines
Philippines
content_provider Ateneo De Manila University Library
collection archium.Ateneo Institutional Repository
topic training
vibrations
ventilators
buildings
prototypes
lung
machine learning
COVID-19
breathing device
hospital informatics
critical care
internet of medical things
near cloud
Analytical, Diagnostic and Therapeutic Techniques and Equipment
Artificial Intelligence and Robotics
Computer Sciences
Diagnosis
Health Information Technology
Respiratory Therapy
spellingShingle training
vibrations
ventilators
buildings
prototypes
lung
machine learning
COVID-19
breathing device
hospital informatics
critical care
internet of medical things
near cloud
Analytical, Diagnostic and Therapeutic Techniques and Equipment
Artificial Intelligence and Robotics
Computer Sciences
Diagnosis
Health Information Technology
Respiratory Therapy
Cabacungan, Paul M.
Oppus, Carlos M.
Cabacungan, Nerissa G.
Marmadlo, John Paul A.
Santiago, Paul Ryan A.
Mercado, Neil Angelo M
Faustino, E. Vincent S.
Tangonan, Gregory L
Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning
description We designed and developed a low-cost mechanical ventilator prototype that meets the government's minimum viable standards. We substituted alternative off-the-shelf food-grade for the medical-grade parts and improvised some components for our prototype. We cleaned the air from the oxygen tanks and compressors before going to the lung test bag. We designed a solar-powered battery system that can run electronic components for a fail-safe operation. We demonstrated how the AIC Near Cloud system can store air flow rate and air pressure data which were generated during the prototype's operation. We used Embedded Machine Learning in sensors and data processing by using flow and pressure sensors to provide accumulated data that can be utilized in training the machine learning software. The patient-ventilator asynchrony detection model was tested using data generated from the emulated ventilator waveform events that mimic the patient-ventilator asynchrony. A different compression pattern was applied to the test lung and results showed the training, validation, and model testing that yielded 98.7%, 99.1%, and 97.18 percent accuracy, respectively. Having demonstrated that the Tiny ML can be trained to detect anomalies from several data points, we realized the feasibility of detecting ventilator patient vibration anomaly, and unusual acoustic signatures, among others, for future works.
format text
author Cabacungan, Paul M.
Oppus, Carlos M.
Cabacungan, Nerissa G.
Marmadlo, John Paul A.
Santiago, Paul Ryan A.
Mercado, Neil Angelo M
Faustino, E. Vincent S.
Tangonan, Gregory L
author_facet Cabacungan, Paul M.
Oppus, Carlos M.
Cabacungan, Nerissa G.
Marmadlo, John Paul A.
Santiago, Paul Ryan A.
Mercado, Neil Angelo M
Faustino, E. Vincent S.
Tangonan, Gregory L
author_sort Cabacungan, Paul M.
title Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning
title_short Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning
title_full Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning
title_fullStr Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning
title_full_unstemmed Design and Development of A-vent: A Low-Cost Ventilator with Cost-Effective Mobile Cloud Caching and Embedded Machine Learning
title_sort design and development of a-vent: a low-cost ventilator with cost-effective mobile cloud caching and embedded machine learning
publisher Archīum Ateneo
publishDate 2021
url https://archium.ateneo.edu/ecce-faculty-pubs/95
https://ieeexplore.ieee.org/document/9550920
_version_ 1722366526621745152

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