Real-Time Risk Assessment Detection for Weak People by Parallel Training Logical Execution of a Supervised Learning System Based on an IoT Wearable MEMS Accelerometer

Activity monitoring has become a necessary demand for weak people to guarantee their safety. The paper proposed a Parallel Training Logical Execution (PTLE) system using machine learning (ML) models on a microelectromechanical system (MEMS) accelerometer to detect coughs, falls, and other normal activities. When there are many categories, the ML prediction can be confused between these activities with each other. The PTLE system trains several models in parallel with more specific activity classes in each dataset. The shared tasks between parallel models relieve the complexity for a single one. There are six additional parameters for accelerometer characteristics, which were calculated from three axes accelerations as input features to improve the ML’s consciousness. Once all models were trained, the system was ready to receive the input accelerations and activated the logical flow to manage link operation between these ML models for output predictions. Random Forest (RF) had the highest potential among the ML classification algorithms after the validation. In the experiment, the comparison between the PTLE model and the regular ML model were carried out with real-time data from an M5stickC wearable device on the user’s chest to the trained models on PC. The result showed the advancement of the proposed method in term of precision, recall, F1-score with an overall accuracy of 98% in the real-time test. The accelerations from the wearable device were sent to ML models via Wi-Fi with Message Queue Telemetry Transport (MQTT) broker, and the activity predictions were transferred to the cloud for the family members or doctor care based on Internet of Things (IoT) communication.

[1]  A. Pietrosanto,et al.  Yaw/Heading optimization by Machine learning model based on MEMS magnetometer under harsh conditions , 2022, Measurement.

[2]  M. Wajid,et al.  Classification of Human Motion Activities using Mobile Phone Sensors and Deep Learning Model , 2022, 2022 8th International Conference on Advanced Computing and Communication Systems (ICACCS).

[3]  Jaewon Shin,et al.  Robust Human Activity Recognition by Integrating Image and Accelerometer Sensor Data Using Deep Fusion Network , 2021, Sensors.

[4]  Kerstin Bach,et al.  HARTH: A Human Activity Recognition Dataset for Machine Learning , 2021, Sensors.

[5]  Antonio Pietrosanto,et al.  New Artificial Intelligence Approach to Inclination Measurement Based on MEMS Accelerometer , 2021, IEEE Transactions on Artificial Intelligence.

[6]  A. Pietrosanto,et al.  Body Temperature—Indoor Condition Monitor and Activity Recognition by MEMS Accelerometer Based on IoT-Alert System for People in Quarantine Due to COVID-19 , 2021, Sensors.

[7]  Antonio Pietrosanto,et al.  Yaw/Heading optimization by drift elimination on MEMS gyroscope , 2021, Sensors and Actuators A: Physical.

[8]  A. Mitiche,et al.  Physical Activity Recognition Based on a Parallel Approach for an Ensemble of Machine Learning and Deep Learning Classifiers , 2021, Sensors.

[9]  Antonio Pietrosanto,et al.  A Robust Orientation System for Inclinometer With Full-Redundancy in Heavy Industry , 2021, IEEE Sensors Journal.

[10]  Thomas Brunschwiler,et al.  An Unsupervised Behavioral Modeling and Alerting System Based on Passive Sensing for Elderly Care , 2020, Future Internet.

[11]  R. Priyamvadaa Temperature and Saturation level monitoring system using MQTT for COVID-19 , 2020, 2020 International Conference on Recent Trends on Electronics, Information, Communication & Technology (RTEICT).

[12]  R. Poovendran,et al.  Design of Cost-effective Wearable Sensors with integrated Health Monitoring System , 2020, 2020 Fourth International Conference on I-SMAC (IoT in Social, Mobile, Analytics and Cloud) (I-SMAC).

[13]  A. Pietrosanto,et al.  A New Technique for Optimization of Linear Displacement Measurement based on MEMS Accelerometer , 2020, 2020 International Semiconductor Conference (CAS).

[14]  Antonio Pietrosanto,et al.  An Effective Method on Vibration Immunity for Inclinometer based on MEMS Accelerometer , 2020, 2020 International Semiconductor Conference (CAS).

[15]  Haibing Yuan,et al.  Design of Temperature and Humidity Detection System for a Material Warehouse Based on GM , 2020, 2020 IEEE 4th Information Technology, Networking, Electronic and Automation Control Conference (ITNEC).

[16]  Vincenzo Paciello,et al.  Pre-Processing Technique for Compass-less Madgwick in Heading Estimation for Industry 4.0 , 2020, 2020 IEEE International Instrumentation and Measurement Technology Conference (I2MTC).

[17]  Joe Hasell,et al.  Coronavirus disease (COVID-19) , 2020, Arab Society: A Compendium of Social Statistics.

[18]  L. Mackay,et al.  A Dual-Accelerometer System for Classifying Physical Activity in Children and Adults , 2018, Medicine and science in sports and exercise.

[19]  Sunwoong Choi,et al.  Recognition of Daily Human Activity Using an Artificial Neural Network and Smartwatch , 2018, Wirel. Commun. Mob. Comput..

[20]  Sakorn Mekruksavanich,et al.  Smartwatch-based sitting detection with human activity recognition for office workers syndrome , 2018, 2018 International ECTI Northern Section Conference on Electrical, Electronics, Computer and Telecommunications Engineering (ECTI-NCON).

[21]  Tahmina Zebin,et al.  Evaluation of supervised classification algorithms for human activity recognition with inertial sensors , 2017, 2017 IEEE SENSORS.

[22]  Yuehong Yin,et al.  The internet of things in healthcare: An overview , 2016, J. Ind. Inf. Integr..

[23]  Thomas George,et al.  An effective approach for human activity recognition on smartphone , 2015, 2015 IEEE International Conference on Engineering and Technology (ICETECH).

[24]  N. A. Zakaria,et al.  Quantitative analysis of fall risk using TUG test , 2015, Computer methods in biomechanics and biomedical engineering.

[25]  Basel Kikhia,et al.  Optimal Placement of Accelerometers for the Detection of Everyday Activities , 2013, Sensors.

[26]  Gaël Varoquaux,et al.  Scikit-learn: Machine Learning in Python , 2011, J. Mach. Learn. Res..

[27]  Ling Bao,et al.  Activity Recognition from User-Annotated Acceleration Data , 2004, Pervasive.

[28]  L. Breiman Random Forests , 2001, Encyclopedia of Machine Learning and Data Mining.

[29]  Vincenzo Paciello,et al.  Measurement Optimization for Orientation Tracking Based on No Motion No Integration Technique , 2021, IEEE Transactions on Instrumentation and Measurement.

[30]  Khan A. Wahid,et al.  COVID-SAFE: An IoT-Based System for Automated Health Monitoring and Surveillance in Post-Pandemic Life , 2020, IEEE Access.

[31]  Tian Ya,et al.  MEMS-based human activity recognition using smartphone , 2016, 2016 35th Chinese Control Conference (CCC).

[32]  Johannes Peltola,et al.  Activity classification using realistic data from wearable sensors , 2006, IEEE Transactions on Information Technology in Biomedicine.

[33]  Daniel Olgu ´ õn,et al.  Human Activity Recognition: Accuracy across Common Locations for Wearable Sensors , 2006 .

[34]  Alois Ferscha,et al.  Pervasive Computing , 2004, Lecture Notes in Computer Science.