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Step length measurement in the wild using FMCW radar (2401.01868v1)

Published 3 Jan 2024 in cs.CV and cs.AI

Abstract: With an aging population, numerous assistive and monitoring technologies are under development to enable older adults to age in place. To facilitate aging in place predicting risk factors such as falls, and hospitalization and providing early interventions are important. Much of the work on ambient monitoring for risk prediction has centered on gait speed analysis, utilizing privacy-preserving sensors like radar. Despite compelling evidence that monitoring step length, in addition to gait speed, is crucial for predicting risk, radar-based methods have not explored step length measurement in the home. Furthermore, laboratory experiments on step length measurement using radars are limited to proof of concept studies with few healthy subjects. To address this gap, a radar-based step length measurement system for the home is proposed based on detection and tracking using radar point cloud, followed by Doppler speed profiling of the torso to obtain step lengths in the home. The proposed method was evaluated in a clinical environment, involving 35 frail older adults, to establish its validity. Additionally, the method was assessed in people's homes, with 21 frail older adults who had participated in the clinical assessment. The proposed radar-based step length measurement method was compared to the gold standard Zeno Walkway Gait Analysis System, revealing a 4.5cm/8.3% error in a clinical setting. Furthermore, it exhibited excellent reliability (ICC(2,k)=0.91, 95% CI 0.82 to 0.96) in uncontrolled home settings. The method also proved accurate in uncontrolled home settings, as indicated by a strong agreement (ICC(3,k)=0.81 (95% CI 0.53 to 0.92)) between home measurements and in-clinic assessments.

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References (37)
  1. Chirp inc. https://mychirp.com/. Accessed: 2023-11-15.
  2. Fcc id 2a9q4-chirp01t. https://fccid.io/2A9Q4-CHIRP01T. Accessed: 2023-11-15.
  3. Ti mmwave-sdk. https://www.ti.com/tool/MMWAVE-SDK. Accessed: 2023-11-15.
  4. Hallway gait monitoring using novel radar signal processing and unsupervised learning. IEEE Sensors Journal, 22(15):15133–15145, 2022.
  5. Hallway gait monitoring system using an in-package integrated dielectric lens paired with a mm-wave radar. Sensors, 23(1), 2023.
  6. Gait speed in clinical and daily living assessments in parkinson’s disease patients: Performance versus capacity. npj Parkinson’s Disease, 7(1):24, 2021.
  7. Walking speed measurement with an ambient measurement system (ams) in patients with multiple sclerosis and walking impairment. Gait & Posture, 61:393–397, 2018.
  8. Contactless gait assessment in home-like environments. Sensors, 21(18):6205, 2021.
  9. Community paramedicine remote patient monitoring (cprpm): Benefits evaluation & lessons learned, 2015/17. Canada Health Infoway, 2018.
  10. I. Bytyçi and M. Y. Henein. Stride length predicts adverse clinical events in older adults: a systematic review and meta-analysis. Journal of Clinical Medicine, 10(12):2670, 2021.
  11. Can failure on adaptive locomotor tasks independently predict incident mobility disability? American journal of physical medicine & rehabilitation/Association of Academic Physiatrists, 92(8):704, 2013.
  12. Estimating the gait speed of older adults in smart home environments. SN Computer Science, 3(2):128, 2022.
  13. S. Fritz and M. Lusardi. White paper:“walking speed: the sixth vital sign”. Journal of geriatric physical therapy, 32(2):2–5, 2009.
  14. A Short Physical Performance Battery Assessing Lower Extremity Function: Association With Self-Reported Disability and Prediction of Mortality and Nursing Home Admission. Journal of Gerontology, 49(2):M85–M94, 03 1994.
  15. J. Hershberger and J. Snoeyink. An o (n log n) implementation of the douglas-peucker algorithm for line simplification. In Proceedings of the tenth annual symposium on Computational geometry, pages 383–384, 1994.
  16. Continuous in-home walking speed monitoring in older people with a low-cost ambient sensor: Results of a feasibility study. Technology and Disability, 33(2):77–85, 2021.
  17. Step length and fall risk in adults with chronic kidney disease: a pilot study. BMC nephrology, 23(1):74, 2022.
  18. A guideline of selecting and reporting intraclass correlation coefficients for reliability research. Journal of chiropractic medicine, 15(2):155–163, 2016.
  19. Prediction of physical frailty in orthogeriatric patients using sensor insole–based gait analysis and machine learning algorithms: cross-sectional study. JMIR Medical Informatics, 10(1):e32724, 2022.
  20. Comparison of gait patterns in elderly fallers and non-fallers. Technology and health care, 26(S1):427–436, 2018.
  21. Monitoring gait at home with radio waves in parkinson’s disease: A marker of severity, progression, and medication response. Science Translational Medicine, 14(663):eadc9669, 2022.
  22. Walking speed: the functional vital sign. Journal of aging and physical activity, 23(2):314–322, 2015.
  23. The montreal cognitive assessment, moca: a brief screening tool for mild cognitive impairment. Journal of the American Geriatrics Society, 53(4):695–699, 2005.
  24. The short performance physical battery is associated with one-year emergency department visits and hospitalization. Canadian Journal on Aging / La Revue canadienne du vieillissement, 38(4):507–511, 2019.
  25. When will my patient fall? sensor-based in-home walking speed identifies future falls in older adults. The Journals of Gerontology: Series A, 75(5):968–973, 2020.
  26. The spatial parameters of gait and their association with falls, functional decline and death in older adults: a prospective study. Scientific reports, 9(1):8813, 2019.
  27. Estimation of gait parameters from trunk movement measured by doppler radar. IEEE Journal of Electromagnetics, RF and Microwaves in Medicine and Biology, 6(4):461–469, 2022.
  28. Doppler radar for the extraction of biomechanical parameters in gait analysis. IEEE Journal of Biomedical and Health Informatics, 25(2):547–558, 2021.
  29. Understanding lstm network behaviour of imu-based locomotion mode recognition for applications in prostheses and wearables. Sensors, 21(4), 2021.
  30. R. Veld. Human gait model individualized by low cost radar measurements, 2023.
  31. Noncontact extraction of biomechanical parameters in gait analysis using a multi-input and multi-output radar sensor. IEEE Access, 9:138496–138508, 2021.
  32. D. Winter. The Biomechanics and Motor Control of Human Gait. University of Waterloo Press, 1987.
  33. Walking speed and stride length predicts 36 months dependency, mortality, and institutionalization in chinese aged 70 and older. Journal of the American Geriatrics Society, 47(10):1257–1260, 1999.
  34. Gait measurement at home using a single rgb camera. Gait & Posture, 76:136–140, 2020.
  35. Development and initial validation of the falls efficacy scale-international (fes-i). Age and ageing, 34(6):614–619, 2005.
  36. Optimization of energy expenditure during level walking. European journal of applied physiology and occupational physiology, 33:293–306, 1974.
  37. mid: Tracking and identifying people with millimeter wave radar. In 2019 15th International Conference on Distributed Computing in Sensor Systems (DCOSS), pages 33–40, 2019.

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