Wearable Sensor-Based Fuzzy Decision-Making Model for Improving the Prediction of Human Activities in Rehabilitation

Abstract Sports actions are commonly recurrent due to the abnormal dynamic human activities. Detecting physical injuries based on the actions of the sportsperson helps to fasten rehabilitation treatments. Rehabilitation relies on the precise detection of activities and continuous monitoring of the actions of the sportsperson. In this paper, wearable sensor-based fuzzy decision-making (FDM) model is introduced for improving the prediction accuracy of different activities of the sportsperson. This model relies on altering sensor data aggregation and processing them using classification conditions for improving the prediction accuracy. The decision-making is performed by linearly classifying independent membership functions for different aggregation time and inputs. The combined processing of the inputs and time-based actions using independent decisions helps to improve the prediction accuracy of 93.3% with 26.081 ms decision time compared to conventional algorithms.

[1]  George Panoutsos,et al.  A Multilayer Interval Type-2 Fuzzy Extreme Learning Machine for the recognition of walking activities and gait events using wearable sensors , 2020, Neurocomputing.

[2]  Feng Xia,et al.  Social acquaintance based routing in Vehicular Social Networks , 2017, Future Gener. Comput. Syst..

[3]  Amr Tolba,et al.  Utilizing IoT wearable medical device for heart disease prediction using higher order Boltzmann model: A classification approach , 2019 .

[4]  Amr Tolba,et al.  MDS: Multi-level decision system for patient behavior analysis based on wearable device information , 2019, Comput. Commun..

[5]  Amanda Watson,et al.  TracKnee: Knee angle measurement using stretchable conductive fabric sensors , 2020, Smart Health.

[6]  Pasquale Daponte,et al.  Design and validation of a motion-tracking system for ROM measurements in home rehabilitation , 2014 .

[7]  P. Mohamed Shakeel,et al.  A dynamic and interoperable communication framework for controlling the operations of wearable sensors in smart healthcare applications , 2020, Comput. Commun..

[8]  Chi Cuong Vu,et al.  Human motion recognition using SWCNT textile sensor and fuzzy inference system based smart wearable , 2018, Sensors and Actuators A: Physical.

[9]  Amr Tolba,et al.  Optimizing the network energy of cloud assisted internet of things by using the adaptive neural learning approach in wireless sensor networks , 2019, Comput. Ind..

[10]  Md. Zia Uddin A wearable sensor-based activity prediction system to facilitate edge computing in smart healthcare system , 2019, J. Parallel Distributed Comput..

[11]  Alberto Leardini,et al.  Kinect and wearable inertial sensors for motor rehabilitation programs at home: state of the art and an experimental comparison , 2020, Biomedical engineering online.

[12]  J. Coombes,et al.  Impact of wearable physical activity monitoring devices with exercise prescription or advice in the maintenance phase of cardiac rehabilitation: systematic review and meta-analysis , 2019, BMC Sports Science, Medicine and Rehabilitation.

[13]  Yanping Jiang,et al.  Combination of wearable sensors and internet of things and its application in sports rehabilitation , 2020, Comput. Commun..

[14]  R. Willy Innovations and pitfalls in the use of wearable devices in the prevention and rehabilitation of running related injuries. , 2018, Physical therapy in sport : official journal of the Association of Chartered Physiotherapists in Sports Medicine.

[15]  Jian Wang,et al.  Big data analysis and research on consumption demand of sports fitness leisure activities , 2018, Cluster Computing.

[16]  Maria Fazio,et al.  Information management in IoT cloud-based tele-rehabilitation as a service for smart cities: Comparison of NoSQL approaches , 2020 .

[17]  Amr Tolba,et al.  Soft computing approaches based bookmark selection and clustering techniques for social tagging systems , 2019, Cluster Computing.

[18]  Ahmed M. Soliman,et al.  Analyzing patient health information based on IoT sensor with AI for improving patient assistance in the future direction , 2020 .

[19]  Nazli Ikizler-Cinbis,et al.  Collective Sports: A multi-task dataset for collective activity recognition , 2020, Image Vis. Comput..

[20]  Juan M. Cortell-Tormo,et al.  Lumbatex: A Wearable Monitoring System Based on Inertial Sensors to Measure and Control the Lumbar Spine Motion , 2019, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[21]  Ayman Habib,et al.  OpenSim: Open-Source Software to Create and Analyze Dynamic Simulations of Movement , 2007, IEEE Transactions on Biomedical Engineering.

[22]  Amr Tolba,et al.  A big data approach to sentiment analysis using greedy feature selection with cat swarm optimization-based long short-term memory neural networks , 2018, The Journal of Supercomputing.

[23]  Stephen A. Billings,et al.  Real-Life Measurement of Tri-Axial Walking Ground Reaction Forces Using Optimal Network of Wearable Inertial Measurement Units , 2018, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[24]  Alessandro Tognetti,et al.  Supervised Recovery of Shoulder Muscular Skeletal Disorders Through a Wearable-Enabled Digital Application , 2019 .

[25]  G. Nassis,et al.  Current Approaches to the Use of Artificial Intelligence for Injury Risk Assessment and Performance Prediction in Team Sports: a Systematic Review , 2019, Sports Medicine - Open.

[26]  George Kordatos,et al.  Design and evaluation of a wearable system to increase adherence to rehabilitation programmes in acute cruciate ligament (CL) rupture , 2019, Multimedia Tools and Applications.

[27]  Ramdane Maamri,et al.  A fuzzy agent approach for smart data extraction in big data environments , 2020, J. King Saud Univ. Comput. Inf. Sci..

[28]  Md. Abdul Momin,et al.  Foot pressure sensor system made from MWCNT coated cotton fibers to monitor human activities , 2020 .

[29]  Zhao Zhang,et al.  Human Activity Recognition Based on Motion Sensor Using U-Net , 2019, IEEE Access.

[30]  Paul T. Sheeba,et al.  Fuzzy dragon deep belief neural network for activity recognition using hierarchical skeleton features , 2019, Evol. Intell..

[31]  Shi Qiang Liu,et al.  A Wearable Flow-MIMU Device for Monitoring Human Dynamic Motion , 2020, IEEE Transactions on Neural Systems and Rehabilitation Engineering.

[32]  P. Mohamed Shakeel,et al.  Automatic Human Emotion Classification in Web Document Using Fuzzy Inference System (FIS): Human Emotion Classification , 2020, Int. J. Technol. Hum. Interact..

[33]  Hassan Fouad,et al.  Magnetic resonance imaging evaluation of vertebral tumor prediction using hierarchical hidden Markov random field model on Internet of Medical Things (IOMT) platform , 2020, Measurement.

[34]  Haytham Al-Feel,et al.  Distributed and scalable computing framework for improving request processing of wearable IoT assisted medical sensors on pervasive computing system , 2020, Comput. Commun..

[35]  Feng Xia,et al.  BoDMaS: Bio-inspired Selfishness Detection and Mitigation in Data Management for Ad-hoc Social Networks , 2017, Ad Hoc Networks.

[36]  P. Mohamed Shakeel,et al.  Echocardiography image segmentation using feed forward artificial neural network (FFANN) with fuzzy multi-scale edge detection (FMED) , 2019, International Journal of Signal and Imaging Systems Engineering.

[37]  Bo Zhou,et al.  A Hybrid Hierarchical Framework for Gym Physical Activity Recognition and Measurement Using Wearable Sensors , 2019, IEEE Internet of Things Journal.

[38]  Kathryn L. Havens,et al.  Accelerations from wearable accelerometers reflect knee loading during running after anterior cruciate ligament reconstruction , 2018, Clinical biomechanics.

[39]  Gunasekaran Manogaran,et al.  Wearable IoT Smart-Log Patch: An Edge Computing-Based Bayesian Deep Learning Network System for Multi Access Physical Monitoring System , 2019, Sensors.