Toward Ultra-Low-Power Remote Health Monitoring: An Optimal and Adaptive Compressed Sensing Framework for Activity Recognition

Activity recognition, as an important component of behavioral monitoring and intervention, has attracted enormous attention, especially in Mobile Cloud Computing (MCC) and Remote Health Monitoring (RHM) paradigms. While recently resource constrained wearable devices have been gaining popularity, their battery life is limited and constrained by the frequent wireless transmission of data to more computationally powerful back-ends. This paper proposes an ultra-low power activity recognition system using a novel adaptive compressed sensing technique that aims to minimize transmission costs. Coarse-grained on-body sensor localization and unsupervised clustering modules are devised to autonomously reconfigure the compressed sensing module for further power saving. We perform a thorough heuristic optimization using Grammatical Evolution (GE) to ensure minimal computation overhead of the proposed methodology. Our evaluation on a real-world dataset and a low power wearable sensing node demonstrates that our approach can reduce the energy consumption of the wireless data transmission up to 81.2 and 61.5 percent, with up to 60.6 and 35.0 percent overall power savings in comparison with baseline and a naive state-of-the-art approaches, respectively. These solutions lead to an average activity recognition accuracy of 89.0 percent—only 4.8 percent less than the baseline accuracy—while having a negligible energy overhead of on-node computation.

[1]  Donald W. Bouldin,et al.  A Cluster Separation Measure , 1979, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[2]  Anthony Rowe,et al.  Location and Activity Recognition Using eWatch: A Wearable Sensor Platform , 2006, Ambient Intelligence in Everyday.

[3]  James A. Landay,et al.  The Mobile Sensing Platform: An Embedded Activity Recognition System , 2008, IEEE Pervasive Computing.

[4]  Leo Breiman,et al.  Random Forests , 2001, Machine Learning.

[5]  Simon A. Dobson,et al.  Energy-Efficient Sensing in Wireless Sensor Networks Using Compressed Sensing , 2014, Sensors.

[6]  Ian H. Witten,et al.  The WEKA data mining software: an update , 2009, SKDD.

[7]  Balas K. Natarajan,et al.  Sparse Approximate Solutions to Linear Systems , 1995, SIAM J. Comput..

[8]  Hassan Ghasemzadeh,et al.  Adaptive compressed sensing at the fingertip of Internet-of-Things sensors: An ultra-low power activity recognition , 2017, Design, Automation & Test in Europe Conference & Exhibition (DATE), 2017.

[9]  José Ignacio Hidalgo,et al.  Multi-objective optimization of dynamic memory managers using grammatical evolution , 2011, GECCO '11.

[10]  Hassan Ghasemzadeh,et al.  Power-Aware Computing in Wearable Sensor Networks: An Optimal Feature Selection , 2015, IEEE Transactions on Mobile Computing.

[11]  Billur Barshan,et al.  Recognizing Daily and Sports Activities in Two Open Source Machine Learning Environments Using Body-Worn Sensor Units , 2014, Comput. J..

[12]  José L. Risco-Martín,et al.  Grammatical Evolutionary Techniques for Prompt Migraine Prediction , 2016, GECCO.

[13]  Emmanuel J. Candès,et al.  Robust uncertainty principles: exact signal reconstruction from highly incomplete frequency information , 2004, IEEE Transactions on Information Theory.

[14]  David Atienza,et al.  An Ultra-Low-Power Application-Specific Processor with Sub-VT Memories for Compressed Sensing , 2012, VLSI-SoC.

[15]  Harinath Garudadri,et al.  An Ultra Low Power Pulse Oximeter Sensor Based on Compressed Sensing , 2009, 2009 Sixth International Workshop on Wearable and Implantable Body Sensor Networks.

[16]  Mario Gerla,et al.  Energy-Efficient Accelerometer Data Transfer for Human Body Movement Studies , 2010, 2010 IEEE International Conference on Sensor Networks, Ubiquitous, and Trustworthy Computing.

[17]  Samee Ullah Khan,et al.  Future Generation Computer Systems ( ) – Future Generation Computer Systems towards Secure Mobile Cloud Computing: a Survey , 2022 .

[18]  David K. Y. Yau,et al.  JICE: Joint data compression and encryption for wireless energy auditing networks , 2015, 2015 12th Annual IEEE International Conference on Sensing, Communication, and Networking (SECON).

[19]  J. Winkler,et al.  Unbiased and Mobile Gait Analysis Detects Motor Impairment in Parkinson's Disease , 2013, PloS one.

[20]  Kalyanmoy Deb,et al.  A fast and elitist multiobjective genetic algorithm: NSGA-II , 2002, IEEE Trans. Evol. Comput..

[21]  Szi-Wen Chen,et al.  Compressed Sensing Technology-Based Spectral Estimation of Heart Rate Variability Using the Integral Pulse Frequency Modulation Model , 2014, IEEE Journal of Biomedical and Health Informatics.

[22]  E.J. Candes,et al.  An Introduction To Compressive Sampling , 2008, IEEE Signal Processing Magazine.

[23]  S. Frick,et al.  Compressed Sensing , 2014, Computer Vision, A Reference Guide.

[24]  Henry A. Kautz,et al.  Fine-grained activity recognition by aggregating abstract object usage , 2005, Ninth IEEE International Symposium on Wearable Computers (ISWC'05).

[25]  E. Candes,et al.  11-magic : Recovery of sparse signals via convex programming , 2005 .

[26]  Yoshihiro Kawahara,et al.  Compressed sensing method for human activity sensing using mobile phone accelerometers , 2012, 2012 Ninth International Conference on Networked Sensing (INSS).

[27]  Cem Ersoy,et al.  Wireless sensor networks for healthcare: A survey , 2010, Comput. Networks.

[28]  Sajal K. Das,et al.  HARKE: Human Activity Recognition from Kinetic Energy Harvesting Data in Wearable Devices , 2018, IEEE Transactions on Mobile Computing.

[29]  Sabine Van Huffel,et al.  Compressed Sensing of Multichannel EEG Signals: The Simultaneous Cosparsity and Low-Rank Optimization , 2015, IEEE Transactions on Biomedical Engineering.

[30]  Marina Zapater,et al.  Power-awareness and smart-resource management in embedded computing systems , 2015, 2015 International Conference on Hardware/Software Codesign and System Synthesis (CODES+ISSS).

[31]  Mahbub Hassan,et al.  CapSense: Capacitor-based Activity Sensing for Kinetic Energy Harvesting Powered Wearable Devices , 2017, MobiQuitous.

[32]  Ulf Jensen,et al.  Mobile Recording System for Sport Applications , 2011 .

[33]  Ting Sun,et al.  Single-pixel imaging via compressive sampling , 2008, IEEE Signal Process. Mag..

[34]  Pierre Vandergheynst,et al.  Compressed Sensing for Real-Time Energy-Efficient ECG Compression on Wireless Body Sensor Nodes , 2011, IEEE Transactions on Biomedical Engineering.

[35]  Guillermo Sapiro,et al.  Adaptive temporal compressive sensing for video , 2013, 2013 IEEE International Conference on Image Processing.

[36]  Carmen C. Y. Poon,et al.  Unobtrusive Sensing and Wearable Devices for Health Informatics , 2014, IEEE Transactions on Biomedical Engineering.

[37]  Alex Mihailidis,et al.  A Survey on Ambient-Assisted Living Tools for Older Adults , 2013, IEEE Journal of Biomedical and Health Informatics.

[38]  Hassan Ghasemzadeh,et al.  Toward seamless wearable sensing: Automatic on-body sensor localization for physical activity monitoring , 2014, 2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[39]  Conor Ryan,et al.  Grammatical Evolution: A Steady State approach , 2008 .

[40]  B. Steele,et al.  Quantitating physical activity in COPD using a triaxial accelerometer. , 2000, Chest.

[41]  T. Blumensath,et al.  Theory and Applications , 2011 .

[42]  Nicholas D. Lane,et al.  From smart to deep: Robust activity recognition on smartwatches using deep learning , 2016, 2016 IEEE International Conference on Pervasive Computing and Communication Workshops (PerCom Workshops).