Extending the battery lifetime of wearable sensors with embedded machine learning

Smart health home systems and assisted living architectures rely on severely energy-constrained sensing devices, such as wearable sensors, for the generation of data and their reliable wireless communication to a central location. However, the need for recharging the battery regularly constitutes a maintenance burden that hinders the long-term cost-effectiveness of these systems, especially for health-oriented applications that target people in need, such as the elderly or the chronically ill. These sensing systems generate raw data that is processed into knowledge by reasoning and machine learning algorithms. This paper investigates the benefits of embedded machine learning, i.e. executing this knowledge extraction on the wearable sensor, instead of communicating abundant raw data over the low power network. Focusing on a simple classification task and using an accelerometer-based wearable sensor, we demonstrate that embedded machine learning has the potential to reduce the radio and processor duty cycle by several orders of magnitude; and, thus, substantially extend the battery lifetime of resource-constrained wearable sensors.

[1]  Davide Anguita,et al.  A Public Domain Dataset for Human Activity Recognition using Smartphones , 2013, ESANN.

[2]  R. Kitchin,et al.  Big Data, new epistemologies and paradigm shifts , 2014, Big Data Soc..

[3]  Adam Dunkels,et al.  Contiki - a lightweight and flexible operating system for tiny networked sensors , 2004, 29th Annual IEEE International Conference on Local Computer Networks.

[4]  Mi Zhang,et al.  USC-HAD: a daily activity dataset for ubiquitous activity recognition using wearable sensors , 2012, UbiComp.

[5]  Sebastian Mödersheim,et al.  Detecting and Preventing Beacon Replay Attacks in Receiver-Initiated MAC Protocols for Energy Efficient WSNs , 2013, NordSec.

[6]  Kuncup Iswandy,et al.  Feature selection with acquisition cost for optimizing sensor system design , 2006 .

[7]  Peter H. N. de With,et al.  Real-time embedded face recognition for smart home , 2005, IEEE Transactions on Consumer Electronics.

[8]  Robert J. Piechocki,et al.  Designing Wearable Sensing Platforms for Healthcare in a Residential Environment , 2017, EAI Endorsed Trans. Pervasive Health Technol..

[9]  Ming Tan,et al.  Cost-sensitive learning of classification knowledge and its applications in robotics , 2004, Machine Learning.

[10]  Lovepreet Kaur,et al.  Energy-Efficient Routing Protocols in Wireless Sensor Networks: A Survey , 2014 .

[11]  D. Altman,et al.  Preparing raw clinical data for publication: guidance for journal editors, authors, and peer reviewers , 2010, BMJ : British Medical Journal.

[12]  Björn Eskofier,et al.  Approaching the accuracy–cost conflict in embedded classification system design , 2016, Pattern Analysis and Applications.

[13]  Thea J. M. Kooiman,et al.  Reliability and validity of ten consumer activity trackers , 2015, BMC Sports Science, Medicine and Rehabilitation.

[14]  Thomas Plötz,et al.  Optimising sampling rates for accelerometer-based human activity recognition , 2016, Pattern Recognit. Lett..

[15]  Theodore Tryfonas,et al.  Privacy Leakage of Physical Activity Levels in Wireless Embedded Wearable Systems , 2017, IEEE Signal Processing Letters.

[16]  Andrea Boni,et al.  Low-Power and Low-Cost Implementation of SVMs for Smart Sensors , 2007, IEEE Transactions on Instrumentation and Measurement.

[17]  Roozbeh Jafari,et al.  Ultra-Low Power Digitally Operated Tunable MEMS Accelerometer , 2016, IEEE Sensors Journal.

[18]  Miguel A. Labrador,et al.  A Survey on Human Activity Recognition using Wearable Sensors , 2013, IEEE Communications Surveys & Tutorials.

[19]  Niall Twomey,et al.  SPHERE: A sensor platform for healthcare in a residential environment , 2017 .

[20]  Robert Simon Sherratt,et al.  SPW-1: A Low-Maintenance Wearable Activity Tracker for Residential Monitoring and Healthcare Applications , 2016, eHealth 360°.

[21]  Guang-Zhong Yang,et al.  Deep learning for human activity recognition: A resource efficient implementation on low-power devices , 2016, 2016 IEEE 13th International Conference on Wearable and Implantable Body Sensor Networks (BSN).

[22]  Lior Rokach,et al.  The CASH algorithm-cost-sensitive attribute selection using histograms , 2013, Inf. Sci..

[23]  Jean-Yves Fourniols,et al.  Smart wearable systems: Current status and future challenges , 2012, Artif. Intell. Medicine.

[24]  Nadir N. Charniya Design of Near-Optimal Classifier Using Multi-Layer Perceptron Neural Networks for Intelligent Sensors , 2013 .

[25]  Robert J. Piechocki,et al.  Mitigating packet loss in connectionless Bluetooth Low Energy , 2015, 2015 IEEE 2nd World Forum on Internet of Things (WF-IoT).

[26]  Naveen Verma,et al.  A Low-Power Processor With Configurable Embedded Machine-Learning Accelerators for High-Order and Adaptive Analysis of Medical-Sensor Signals , 2013, IEEE Journal of Solid-State Circuits.

[27]  Jaehyuk Choi,et al.  A 3.4-$\mu$ W Object-Adaptive CMOS Image Sensor With Embedded Feature Extraction Algorithm for Motion-Triggered Object-of-Interest Imaging , 2014, IEEE Journal of Solid-State Circuits.

[28]  Eric Panken,et al.  A micropower support vector machine based seizure detection architecture for embedded medical devices , 2009, 2009 Annual International Conference of the IEEE Engineering in Medicine and Biology Society.

[29]  Shijun Wang,et al.  Real-time detection and classification of machine parts with embedded system for industrial robot grasping , 2015, 2015 IEEE International Conference on Mechatronics and Automation (ICMA).

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

[31]  Daniel Nikovski,et al.  Incremental exemplar learning schemes for classification on embedded devices , 2008, Machine Learning.

[32]  J. D. Janssen,et al.  Assessment of energy expenditure for physical activity using a triaxial accelerometer. , 1994, Medicine and science in sports and exercise.

[33]  Raluca Marin-Perianu,et al.  Energy-Efficient Assessment of Physical Activity Level Using Duty-Cycled Accelerometer Data , 2011, ANT/MobiWIS.