MDPose: human skeletal motion reconstruction using WiFi micro-doppler signatures
MDPose: human skeletal motion reconstruction using WiFi micro-doppler signatures
Motion tracking systems based on optical sensors typically suffer from poor lighting conditions, occlusion, limited coverage, and may raise privacy concerns. More recently, radiofrequency (RF) based approaches using commercial WiFi devices have emerged which offer low-cost ubiquitous sensing whilst preservin privacy. However, RF sensing systems typically output range-Doppler maps, time-frequency spectrograms, cross-range plots etc which cannot represent human motion intuitively and usually requires further processing. In this study, we propose MDPose, a novel framework for human skeletal motion reconstruction base on WiFi micro-Doppler signatures. MDPose provides an effective solution to represent human activity by reconstructing a skeleton model with 17 key points, which can assist with the interpretation of conventional RF sensing outputs in a more understandable way. Specifically, MDPose is implemented over three sequential stage to address a series of challenges: First, a denoising algorithm is employed to remove any unwanted noise that may affect feature extraction and enhance weak Doppler measurements. Secondly, a convolutional neural network (CNN)-recurrent neural network (RNN) architecture is applied to learn temporal spatial dependenc from clean micro-Doppler signatures and restore velocity information to key points under the supervision of the motion capture (Mocap) system. Finally, a pose optimisation mechanism based on learning optimisation vectors is employed to estimate the initial state of the skeleton and to limit additional errors. We hav conducted a comprehensive set of tests in a variety of environments using numerous subjects with a single receiver radar system to demonstrate the performance of MDPose, and report 29.4mm mean absolute error over all key points positions on several common daily activities, which has performance comparable to that of state-ofthe- art RF-based pose estimation systems.
Deep Learning, Human Skeletal Motion Reconstruction, Noise reduction, Security, Sensors, Skeleton, Spectrogram, Training, WiFi Sensing Technology, Wireless fidelity
1-12
Tang, Chong
3b45fdeb-c697-4954-b610-644389c06284
Li, Wenda
3a3026d2-6265-4fb9-9b4e-22082087909e
Vishwakarma, Shelly
c98f51e0-a07e-4b21-becd-75d7249643ea
Shi, Fangzhan
4272572e-25fa-4e77-be3e-953400f2278e
Julier, Simon J.
235e7de9-827e-4fb8-bc04-46e93136ac43
Chetty, Kevin
324e29d3-cdf5-4e2b-9b78-5fad57f4e4d0
Tang, Chong
3b45fdeb-c697-4954-b610-644389c06284
Li, Wenda
3a3026d2-6265-4fb9-9b4e-22082087909e
Vishwakarma, Shelly
c98f51e0-a07e-4b21-becd-75d7249643ea
Shi, Fangzhan
4272572e-25fa-4e77-be3e-953400f2278e
Julier, Simon J.
235e7de9-827e-4fb8-bc04-46e93136ac43
Chetty, Kevin
324e29d3-cdf5-4e2b-9b78-5fad57f4e4d0
Tang, Chong, Li, Wenda, Vishwakarma, Shelly, Shi, Fangzhan, Julier, Simon J. and Chetty, Kevin
(2023)
MDPose: human skeletal motion reconstruction using WiFi micro-doppler signatures.
IEEE Transactions on Aerospace and Electronic Systems, .
(doi:10.1109/TAES.2023.3256973).
Abstract
Motion tracking systems based on optical sensors typically suffer from poor lighting conditions, occlusion, limited coverage, and may raise privacy concerns. More recently, radiofrequency (RF) based approaches using commercial WiFi devices have emerged which offer low-cost ubiquitous sensing whilst preservin privacy. However, RF sensing systems typically output range-Doppler maps, time-frequency spectrograms, cross-range plots etc which cannot represent human motion intuitively and usually requires further processing. In this study, we propose MDPose, a novel framework for human skeletal motion reconstruction base on WiFi micro-Doppler signatures. MDPose provides an effective solution to represent human activity by reconstructing a skeleton model with 17 key points, which can assist with the interpretation of conventional RF sensing outputs in a more understandable way. Specifically, MDPose is implemented over three sequential stage to address a series of challenges: First, a denoising algorithm is employed to remove any unwanted noise that may affect feature extraction and enhance weak Doppler measurements. Secondly, a convolutional neural network (CNN)-recurrent neural network (RNN) architecture is applied to learn temporal spatial dependenc from clean micro-Doppler signatures and restore velocity information to key points under the supervision of the motion capture (Mocap) system. Finally, a pose optimisation mechanism based on learning optimisation vectors is employed to estimate the initial state of the skeleton and to limit additional errors. We hav conducted a comprehensive set of tests in a variety of environments using numerous subjects with a single receiver radar system to demonstrate the performance of MDPose, and report 29.4mm mean absolute error over all key points positions on several common daily activities, which has performance comparable to that of state-ofthe- art RF-based pose estimation systems.
Text
MD Pose Human Skeletal motion reconstruction using WIFI Micro-doppler signatures
- Accepted Manuscript
More information
Accepted/In Press date: 2023
e-pub ahead of print date: 26 February 2023
Additional Information:
Publisher Copyright:
IEEE
Keywords:
Deep Learning, Human Skeletal Motion Reconstruction, Noise reduction, Security, Sensors, Skeleton, Spectrogram, Training, WiFi Sensing Technology, Wireless fidelity
Identifiers
Local EPrints ID: 476892
URI: http://eprints.soton.ac.uk/id/eprint/476892
PURE UUID: fa26790a-4e80-4ec9-81d6-13aa6c68c288
Catalogue record
Date deposited: 18 May 2023 16:59
Last modified: 17 Mar 2024 02:11
Export record
Altmetrics
Contributors
Author:
Chong Tang
Author:
Wenda Li
Author:
Shelly Vishwakarma
Author:
Fangzhan Shi
Author:
Simon J. Julier
Author:
Kevin Chetty
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics