Towards Real-Time Partially Self-Calibrating Pedestrian Navigation With an Inertial Sensor Array

Inspired by algorithms utilized in inertial navigation, an inertial motion capturing algorithm capable of position and heading estimation is introduced. The fusion algorithm is capable of real-time link geometry estimation, which allows for the imposition of biomechanical constraints without a prior...

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Bibliographic Details
Published inIEEE sensors journal Vol. 20; no. 12; pp. 6634 - 6641
Main Authors Razavi, H., Salarieh, H., Alasty, A.
Format Journal Article
LanguageEnglish
Published New York IEEE 15.06.2020
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Accelerometers
Algorithms
Biomechanics
Calibration
calibration and identification
Estimation
Gyroscopes
Inertial navigation
Inertial sensing devices
Kalman filters
Motion capture
Neural networks
Optical communication
Orthogonality
Position measurement
Real time
Real-time systems
Root-mean-square errors
Sensor arrays
Sensor fusion
Sensors
unscented filtering
Walking
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Summary:Inspired by algorithms utilized in inertial navigation, an inertial motion capturing algorithm capable of position and heading estimation is introduced. The fusion algorithm is capable of real-time link geometry estimation, which allows for the imposition of biomechanical constraints without a priori knowledge regarding sensor placements. Furthermore, the algorithm estimates gyroscope and accelerometer bias, scaling, and non-orthogonality parameters in real-time. The stationary phases of the links, during which pseudo-measurements such as zero velocity or heading stabilization updates are applied, are detected using optically trained neural networks with buffered accelerometer and gyroscope data as inputs. The estimated position and heading in each link are subject to a limited amount of error relative to the traveled distance, even though the algorithm does not utilize magnetic or external position measurements. The performance of the algorithm, deployed using both extended and square-root unscented Kalman filtering schemes (EKF and SRUKF, respectively), is experimentally evaluated during a fast-paced walking test using a custom-made inertial motion capture system. Comparison with an optical motion capture system shows that, compared to the EKF, the SRUKF performs up to 3 times and 40% better in terms of position and attitude estimation root mean square error (RMSE), respectively.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2020.2974900