Recognizing Human Activity in Free-Living Using Multiple Body-Worn Accelerometers

Fullerton, Elliott; Heller, Ben; Muñoz-Organero, Mario

doi:10.1109/jsen.2017.2722105

Cited by 66 publications

(62 citation statements)

References 25 publications

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“…These methods achieved accuracies between 77.3% and 99%, however, they need a large number of sensors that also limits these works to indoor applications [26], [27]. SVM and knearest neighbour algorithms, together with 9 accelerometers distributed from the torso to the ankle, achieved an accuracy of 97.6% for recognition of ADLs [28]. The combination of plantar pressure sensors with multi-class SVMs allowed the recognition of normal walking, stair ascent and stair descent activities with accuracies between 91.9% and 95.2% [29].…”

Section: Related Workmentioning

confidence: 99%

Simultaneous Bayesian Recognition of Locomotion and Gait Phases With Wearable Sensors

2018

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Section: Related Workmentioning

confidence: 99%

Simultaneous Bayesian Recognition of Locomotion and Gait Phases With Wearable Sensors

2018

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“…Currently, WS-based HMT systems [6] are mainly composed of inertial sensors, such as accelerometers and gyroscopes. However, inertial sensors may inevitably throw off errors that accumulate over time [8,15,25]. The accumulative and drift error is the biggest challenge faced by WS-based HMT systems.…”

Section: Hmt Systems and Applicationsmentioning

confidence: 99%

“…As human motion tracking could be viewed as a multiple-target localization issue of human body joints, tracking accuracy is the most important consideration. However, sensor drift errors and distortion (especially in long time monitoring) are the main problems [8,15,25].…”

Section: Sensor Fusion and Filteringmentioning

confidence: 99%

“…In essence, human motion tracking can be viewed as a local multi-target real-time high-precision three-dimensional positioning problem [23]. Ultra-Wideband (UWB)-based time-of-arrival (TOA) ranging is the most commonly used high-precision localization technology, its measurement accuracy can reach the centimeter level, and it does not have the drawback of accumulative errors, compared with inertial-sensor-based HMT systems [23,25]. The size of TOA chip is small enough to be integrated into wearable devices.…”

mentioning

confidence: 99%

“…Some achievements on IMU/TOA fusion have been reported in many studies (e.g., [20,21,23,25]) However, state-of-the-art studies, (e.g., [23,27]), mainly face the following two drawbacks:…”

mentioning

confidence: 99%

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Towards Human Motion Tracking: Multi-Sensory IMU/TOA Fusion Method and Fundamental Limits

Zhang

et al. 2019

Electronics

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Human motion tracking could be viewed as a multi-target tracking problem towards numerous body joints. Inertial-measurement-unit-based human motion tracking technique stands out and has been widely used in body are network applications. However, it has been facing the tough problem of accumulative errors and drift. In this paper, we propose a multi-sensor hybrid method to solve this problem. Firstly, an inertial-measurement-unit and time-of-arrival fusion-based method is proposed to compensate the drift and accumulative errors caused by inertial sensors. Secondly, Cramér-Rao lower bound is derived in detail with consideration of both spatial and temporal related factors. Simulation results show that the proposed method in this paper has both spatial and temporal advantages, compared with traditional sole inertial or time-of-arrival-based tracking methods. Furthermore, proposed method is verified in 3D practical application scenarios. Compared with state-of-the-art algorithms, proposed fusion method shows better consistency and higher tracking accuracy, especially when moving direction changes. The proposed fusion method and comprehensive fundamental limits analysis conducted in this paper can provide a theoretical basis for further system design and algorithm analysis. Without the requirements of external anchors, the proposed method has good stability and high tracking accuracy, thus it is more suitable for wearable motion tracking applications.

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Sensor‐based activity recognition independent of device placement and orientation

Shi

Zuo

Zhang

et al. 2020

Trans Emerging Tel Tech

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Human activity recognition (HAR) is a prominent subfield of pervasive computing and also provides context of many applications such as healthcare, education, and entertainment. Most wearable HAR studies assume that sensing device placement and orientation are fixed and never change. However, this condition is actually not always guaranteed in the real scenario and recognition result is influenced by the distortion as consequence. To handle this, our work proposes a new model based on convolutional neural network to extract robust features which are invariant of device placement and orientation, to train machine learning classifiers. We first carry out experiments to show negative effects of this problem. Then, we apply the convolutional neural network-based hybrid structure on the HAR. Results show that our method provides 15% to 40% accuracy promotion on public data set and 10% to 20% promotion on our own data set, both with distortion.Trans Emerging Tel Tech. 2020;31:e3823.wileyonlinelibrary.com/journal/ett

show abstract

Recognizing Human Activity in Free-Living Using Multiple Body-Worn Accelerometers

Cited by 66 publications

References 25 publications

Simultaneous Bayesian Recognition of Locomotion and Gait Phases With Wearable Sensors

Simultaneous Bayesian Recognition of Locomotion and Gait Phases With Wearable Sensors

Towards Human Motion Tracking: Multi-Sensory IMU/TOA Fusion Method and Fundamental Limits

Sensor‐based activity recognition independent of device placement and orientation

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