Monitoring Bodily Oscillation With RFID Tags

Traditional systems for monitoring and diagnosing patients’ health conditions often require either dedicated medical devices or complicated system deployment, which incurs high cost. The networking research community has recently taken a different technical approach of building health-monitoring systems at relatively low cost based on wireless signals. However, the radio frequency signals carry various types of noise and have time-varying properties that often defy the existing methods in more demanding conditions with other body movements, which makes it difficult to model and analyze the signals mathematically. In this paper, we design a novel wireless system using commercial off-the-shelf RFID readers and tags to provide a general and effective means of measuring bodily oscillation rates, such as the hand tremor rate of a patient with Parkinson’s disease. Our system includes a series of noise-removal steps, targeting at noise from different sources. More importantly, it introduces two sliding window-based methods to deal with time-varying signal properties from channel dynamics and irregular body movement. The proposed system can measure bodily oscillation rates of multiple persons simultaneously. Extensive experiments show that our system can produce accurate measurement results with errors less than 0.4 oscillations per second when it is applied to monitor hand tremor, even when the individuals are moving.

[1]  D. Farina,et al.  Bioinformatic Approaches Used in Modelling Human Tremor , 2009 .

[2]  M. Littner,et al.  Practice parameters for the indications for polysomnography and related procedures: an update for 2005. , 2005, Sleep.

[3]  Joshua T. Cohen,et al.  Does preventive care save money? Health economics and the presidential candidates. , 2008, The New England journal of medicine.

[4]  Shigang Chen,et al.  Missing-Tag Detection with Presence of Unknown Tags , 2018, 2018 15th Annual IEEE International Conference on Sensing, Communication, and Networking (SECON).

[5]  Yuguang Fang,et al.  Anonymous Temporal-Spatial Joint Estimation at Category Level Over Multiple Tag Sets , 2018, IEEE INFOCOM 2018 - IEEE Conference on Computer Communications.

[6]  Catherine Dehollain,et al.  Gait assessment in Parkinson's disease: toward an ambulatory system for long-term monitoring , 2004, IEEE Transactions on Biomedical Engineering.

[7]  Dharma P. Agrawal,et al.  Detecting Mobility for Monitoring Patients with Parkinson's Disease at Home using RSSI in a Wireless Sensor Network , 2013, ANT/SEIT.

[8]  Rob Miller,et al.  Demo: real-time breath monitoring using wireless signals , 2014, MobiCom.

[9]  R. Pasick,et al.  Perceived Susceptibility to Illness and Perceived Benefits of Preventive Care: An Exploration of Behavioral Theory Constructs in a Transcultural Context , 2009, Health education & behavior : the official publication of the Society for Public Health Education.

[10]  Xu Chen,et al.  Tracking Vital Signs During Sleep Leveraging Off-the-shelf WiFi , 2015, MobiHoc.

[11]  Dan Wu,et al.  Human respiration detection with commodity wifi devices: do user location and body orientation matter? , 2016, UbiComp.

[12]  Ross A. Knepper,et al.  RF-compass: robot object manipulation using RFIDs , 2013, MobiCom.

[13]  David Wetherall,et al.  Tool release: gathering 802.11n traces with channel state information , 2011, CCRV.

[14]  Shigang Chen,et al.  Efficient protocols for identifying the missing tags in a large RFID system , 2013, TNET.

[15]  Guoliang Xing,et al.  iSleep: unobtrusive sleep quality monitoring using smartphones , 2013, SenSys '13.

[16]  Dimitrios I. Fotiadis,et al.  PERFORM: A System for Monitoring, Assessment and Management of Patients with Parkinson's Disease , 2014, Sensors.

[17]  Lei Yang,et al.  See Through Walls with COTS RFID System! , 2015, MobiCom.

[18]  Matt Welsh,et al.  Sensor networks for medical care , 2005, SenSys '05.

[19]  Jennifer G. Dy,et al.  Home monitoring of patients with Parkinson's disease via wearable technology and a web-based application , 2010, 2010 Annual International Conference of the IEEE Engineering in Medicine and Biology.

[20]  Rob Miller,et al.  Smart Homes that Monitor Breathing and Heart Rate , 2015, CHI.

[21]  Lei Yang,et al.  Making sense of mechanical vibration period with sub-millisecond accuracy using backscatter signals , 2016, MobiCom.

[22]  Yanwen Wang,et al.  TagBreathe: Monitor Breathing with Commodity RFID Systems , 2017, 2017 IEEE 37th International Conference on Distributed Computing Systems (ICDCS).

[23]  Yuguang Fang,et al.  An efficient tag search protocol in large-scale RFID systems , 2016, 2013 Proceedings IEEE INFOCOM.

[24]  Jie Wu,et al.  Efficiently collecting histograms over RFID tags , 2014, IEEE INFOCOM 2014 - IEEE Conference on Computer Communications.

[25]  L. Doyle,et al.  Long-term Benefits of Home-based Preventive Care for Preterm Infants: A Randomized Trial , 2012, Pediatrics.

[26]  Patrick C. Walsh,et al.  American Cancer Society guidelines for the early detection of cancer. , 2002, CA: a cancer journal for clinicians.

[27]  Volker Dietz,et al.  Differences in the EMG pattern of leg muscle activation during locomotion in Parkinson's disease. , 2003, Functional neurology.

[28]  Khaled A. Harras,et al.  UbiBreathe: A Ubiquitous non-Invasive WiFi-based Breathing Estimator , 2015, MobiHoc.

[29]  Maurizio Bocca,et al.  Breathfinding: A Wireless Network That Monitors and Locates Breathing in a Home , 2013, IEEE Journal of Selected Topics in Signal Processing.

[30]  W. Manning,et al.  Preventive care: do we practice what we preach? , 1987, American journal of public health.

[31]  I. Johnstone,et al.  Ideal spatial adaptation by wavelet shrinkage , 1994 .

[32]  David Girbau,et al.  ANALYSIS OF VITAL SIGNS MONITORING USING AN IR-UWB RADAR , 2010 .

[33]  Lei Yang,et al.  Tagoram: real-time tracking of mobile RFID tags to high precision using COTS devices , 2014, MobiCom.

[34]  Yifan Chen,et al.  Human respiration rate estimation using ultra-wideband distributed cognitive radar system , 2008, Int. J. Autom. Comput..