Efficient Feature-Selection-Based Stacking Model for Stress Detection Based on Chest Electrodermal Activity

Contemporary advancements in wearable equipment have generated interest in continuously observing stress utilizing various physiological indicators. Early stress detection can improve healthcare by lessening the negative effects of chronic stress. Machine learning (ML) methodologies have been modified for healthcare equipment to monitor user health situations utilizing sufficient user information. Nevertheless, more data are needed to make applying Artificial Intelligence (AI) methodologies in the medical field easier. This research aimed to detect stress using a stacking model based on machine learning algorithms using chest-based features from the Wearable Stress and Affect Detection (WESAD) dataset. We converted this natural dataset into a convenient format for the suggested model by performing data visualization and preprocessing using the RESP feature and feature analysis using the Z-score, SelectKBest feature, the Synthetic Minority Over-Sampling Technique (SMOTE), and normalization. The efficiency of the proposed model was estimated regarding accuracy, precision, recall, and F1-score. The experimental outcome illustrated the efficacy of the proposed stacking technique, achieving 0.99% accuracy. The results revealed that the proposed stacking methodology performed better than traditional methodologies and previous studies.

[1]  M. Greguš,et al.  Automated Cognitive Health Assessment Based on Daily Life Functional Activities , 2023, Computational intelligence and neuroscience.

[2]  Praveen Kumar Reddy Maddikunta,et al.  Artificial Intelligence for Cognitive Health Assessment: State-of-the-Art, Open Challenges and Future Directions , 2023, Cognitive Computation.

[3]  Lirong Yin,et al.  A Feature Matching Method based on the Convolutional Neural Network , 2023, Journal of Imaging Science and Technology.

[4]  M. Krichen,et al.  Real time health care big data analytics model for improved QoS in cardiac disease prediction with IoT devices , 2023, Health and Technology.

[5]  Mideth B. Abisado,et al.  Wrist-Based Electrodermal Activity Monitoring for Stress Detection Using Federated Learning , 2023, Sensors.

[6]  Praveen Kumar Reddy Maddikunta,et al.  A Survey of Explainable Artificial Intelligence for Smart Cities , 2023, Electronics.

[7]  A. R. Javed,et al.  Situation-Aware BDI Reasoning to Detect Early Symptoms of Covid 19 Using Smartwatch , 2022, IEEE Sensors Journal.

[8]  Lirong Yin,et al.  Iterative reconstruction of low-dose CT based on differential sparse , 2023, Biomed. Signal Process. Control..

[9]  Shtwai Alsubai,et al.  Smart Home-Based Complex Interwoven Activities for Cognitive Health Assessment , 2022, Journal of Sensors.

[10]  Shtwai Alsubai,et al.  Ensemble deep learning for brain tumor detection , 2022, Frontiers in Computational Neuroscience.

[11]  Shtwai Alsubai,et al.  Falling and Drowning Detection Framework Using Smartphone Sensors , 2022, Computational intelligence and neuroscience.

[12]  Nawab Muhammad Faseeh Qureshi,et al.  I-Health: SDN-Based Fog Architecture for IIoT Applications in Healthcare. , 2022, IEEE/ACM transactions on computational biology and bioinformatics.

[13]  Khairan D. Rajab,et al.  An Efficient Machine Learning Model Based on Improved Features Selections for Early and Accurate Heart Disease Predication , 2022, Computational Intelligence and Neuroscience.

[14]  Lei Zhou,et al.  Usefulness of Enzyme-Free and Enzyme-Resistant Detection of Complement Component 5 to Evaluate Acute Myocardial Infarction , 2022, Sensors and Actuators B: Chemical.

[15]  T. S. Navruz,et al.  Stress Detection with Deep Learning Using BVP and EDA Signals , 2022, 2022 International Congress on Human-Computer Interaction, Optimization and Robotic Applications (HORA).

[16]  Gautam Srivastava,et al.  Blockchain and PUF-Based Lightweight Authentication Protocol for Wireless Medical Sensor Networks , 2022, IEEE Internet of Things Journal.

[17]  Abdul Rehman Aslam,et al.  Multiphysiological Shallow Neural Network-Based Mental Stress Detection System for Wearable Environment , 2022, 2022 IEEE International Symposium on Circuits and Systems (ISCAS).

[18]  Pai Chet Ng,et al.  Feasibility Study of Stress Detection with Machine Learning through EDA from Wearable Devices , 2022, ICC 2022 - IEEE International Conference on Communications.

[19]  M. A. Faruque,et al.  SELF-CARE: Selective Fusion with Context-Aware Low-Power Edge Computing for Stress Detection , 2022, 2022 18th International Conference on Distributed Computing in Sensor Systems (DCOSS).

[20]  K. Alzoubi,et al.  Machine Learning for Healthcare Wearable Devices: The Big Picture , 2022, Journal of healthcare engineering.

[21]  M. Rizwan,et al.  Machine Learning Assisted Cervical Cancer Detection , 2021, Frontiers in Public Health.

[22]  Nicole D. Aranoff,et al.  Mean Pressure Gradient Prediction Based on Chest Angular Movements and Heart Rate Variability Parameters , 2021, 2021 43rd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC).

[23]  T. Karthick,et al.  RETRACTED ARTICLE: Continuous Activity-Aware Stress Detection Using Sensors , 2021, Wireless Personal Communications.

[24]  Saeed Rubaiee,et al.  Blockchain-assisted secured data management framework for health information analysis based on Internet of Medical Things , 2021, Personal and Ubiquitous Computing.

[25]  Yousaf Bin Zikria,et al.  Future Smart Cities: Requirements, Emerging Technologies, Applications, Challenges, and Future Aspects , 2021 .

[26]  Nitesh V. Chawla,et al.  DeepSMOTE: Fusing Deep Learning and SMOTE for Imbalanced Data , 2021, IEEE Transactions on Neural Networks and Learning Systems.

[27]  Akshi Kumar,et al.  Hierarchical deep neural network for mental stress state detection using IoT based biomarkers , 2021, Pattern Recognit. Lett..

[28]  Andreas Dengel,et al.  Stress Detection by Machine Learning and Wearable Sensors , 2021, IUI Companion.

[29]  S. Rubaiee,et al.  An IoT Framework for Screening of COVID-19 Using Real-Time Data from Wearable Sensors , 2021, International journal of environmental research and public health.

[30]  J. Shieh,et al.  Pain and Stress Detection Using Wearable Sensors and Devices—A Review , 2021, Sensors.

[31]  Waleed S. Alnumay,et al.  PP-SPA: Privacy Preserved Smartphone-Based Personal Assistant to Improve Routine Life Functioning of Cognitive Impaired Individuals , 2021, Neural Processing Letters.

[32]  Zhandong Liu,et al.  Stress detection using deep neural networks , 2020, BMC Medical Informatics and Decision Making.

[33]  Gautam Srivastava,et al.  Automated cognitive health assessment in smart homes using machine learning , 2020 .

[34]  Azana Hafizah Mohd Aman,et al.  Internet of Things and Its Applications: A Comprehensive Survey , 2020, Symmetry.

[35]  Thar Baker,et al.  A collaborative healthcare framework for shared healthcare plan with ambient intelligence , 2020, Hum. centric Comput. Inf. Sci..

[36]  J. Hayano,et al.  Quantitative detection of sleep apnea with wearable watch device , 2020, bioRxiv.

[37]  Maili Liu,et al.  Hyperpolarized Xe NMR signal advancement by metal-organic framework entrapment in aqueous solution , 2020, Proceedings of the National Academy of Sciences.

[38]  Ali Kashif Bashir,et al.  PARCIV: Recognizing physical activities having complex interclass variations using semantic data of smartphone , 2020, Softw. Pract. Exp..

[39]  Franca Delmastro,et al.  Cognitive Training and Stress Detection in MCI Frail Older People Through Wearable Sensors and Machine Learning , 2020, IEEE Access.

[40]  Celestine Iwendi,et al.  Analyzing the Effectiveness and Contribution of Each Axis of Tri-Axial Accelerometer Sensor for Accurate Activity Recognition , 2020, Sensors.

[41]  Tyler L. Hayes,et al.  Lifelong Machine Learning with Deep Streaming Linear Discriminant Analysis , 2019, 2020 IEEE/CVF Conference on Computer Vision and Pattern Recognition Workshops (CVPRW).

[42]  Sotiris B. Kotsiantis,et al.  Stacking Strong Ensembles of Classifiers , 2019, AIAI.

[43]  Vaibhav Gupta,et al.  Detection of Spatial Outlier by Using Improved Z-Score Test , 2019, 2019 3rd International Conference on Trends in Electronics and Informatics (ICOEI).

[44]  Kristof Van Laerhoven,et al.  Introducing WESAD, a Multimodal Dataset for Wearable Stress and Affect Detection , 2018, ICMI.

[45]  Adriana Arza Valdés,et al.  Measuring acute stress response through physiological signals: towards a quantitative assessment of stress , 2018, Medical & Biological Engineering & Computing.

[46]  David Ellis,et al.  Stress Detection Using Wearable Physiological and Sociometric Sensors , 2017, Int. J. Neural Syst..

[47]  István Vassányi,et al.  Stress Detection Using Low Cost Heart Rate Sensors , 2016, Journal of healthcare engineering.

[48]  Lirong Yin,et al.  Analysis and Design of Surgical Instrument Localization Algorithm , 2023, Computer Modeling in Engineering & Sciences.

[49]  N. Kryvinska,et al.  An Ensemble Machine Learning Technique for Stroke Prognosis , 2023, Comput. Syst. Sci. Eng..

[50]  M. Alazab,et al.  InfusedHeart: A Novel Knowledge-Infused Learning Framework for Diagnosis of Cardiovascular Events , 2022, IEEE Transactions on Computational Social Systems.

[51]  Sanchita Paul,et al.  A Review on Mental Stress Detection Using Wearable Sensors and Machine Learning Techniques , 2021, IEEE Access.

[52]  Shahan Yamin Siddiqui,et al.  IoMT Cloud-Based Intelligent Prediction of Breast Cancer Stages Empowered With Deep Learning , 2021, IEEE Access.

[53]  Barween Al Kurdi,et al.  IoT for Smart Cities: Machine Learning Approaches in Smart Healthcare - A Review , 2021, Future Internet.

[54]  Shruti Garg,et al.  Predicting Anxiety, Depression and Stress in Modern Life using Machine Learning Algorithms , 2020 .

[55]  Kristin L. Sainani,et al.  Logistic Regression , 2014, PM & R : the journal of injury, function, and rehabilitation.

[56]  Rodrigo Siqueira Reis,et al.  Perceived stress scale: reliability and validity study in Brazil. , 2010, Journal of health psychology.

[57]  Nitesh V. Chawla,et al.  SMOTE: Synthetic Minority Over-sampling Technique , 2002, J. Artif. Intell. Res..