Abstract
Stride length and walking distance estimation are becoming a key aspect of many applications. One of the methods of enhancing the accuracy of pedestrian dead reckoning is to accurately estimate the stride length of pedestrians. Existing stride length estimation (SLE) algorithms present good performance in the cases of walking at normal speed and the fixed smartphone mode (handheld). The mode represents a specific state of the carried smartphone. The error of existing SLE algorithms increases in complex scenes with many mode changes. Considering that stride length estimation is very sensitive to smartphone modes, this paper focused on combining smartphone mode recognition and stride length estimation to provide an accurate walking distance estimation. We combined multiple classification models to recognize five smartphone modes (calling, handheld, pocket, armband, swing). In addition to using a combination of time-domain and frequency-domain features of smartphone built-in accelerometers and gyroscopes during the stride interval, we constructed higher-order features based on the acknowledged studies (Kim, Scarlett, and Weinberg) to model stride length using the regression model of machine learning. In the offline phase, we trained the corresponding stride length estimation model for each mode. In the online prediction stage, we called the corresponding stride length estimation model according to the smartphone mode of a pedestrian. To train and evaluate the performance of our SLE, a dataset with smartphone mode, actual stride length, and total walking distance were collected. We conducted extensive and elaborate experiments to verify the performance of the proposed algorithm and compare it with the state-of-the-art SLE algorithms. Experimental results demonstrated that the proposed walking distance estimation method achieved significant accuracy improvement over existing individual approaches when a pedestrian was walking in both indoor and outdoor complex environments with multiple mode changes.
Highlights
Applications that attempt to track pedestrian motion level for health purposes require an accurate step detection and stride length estimation (SLE) technique [1]
Stride length estimation is a key component of pedestrian dead reckoning (PDR), the accuracy of which will directly affect the performance of PDR systems
The five-fold cross-validation method was used to verify the performance of the proposed smartphone mode recognition method
Summary
Applications that attempt to track pedestrian motion level (walking distance) for health purposes require an accurate step detection and stride length estimation (SLE) technique [1]. In addition to providing more accurate motion level estimation, precise stride length estimation based on built-in smartphone inertial sensors enhances positioning accuracy of PDR. Stride length and walking distance estimation from smartphones’ inertial sensors are challenging because of the various walking patterns and smartphone carrying methods These SLE algorithms perform well in the case of walking at normal speed under fixed mode. We fused multiple regression predictions from different regression models in machine learning using a stacking regression model, so that we obtained an optimal stride length estimation accuracy with an error rate of 3.30%, dependent only on the embedded smartphone inertial sensor data. We established a benchmark dataset with ground truth from a FM-INS (foot-mounted inertial navigation system, x-IMU [39] from x-io technologies) module for step counting, smartphone mode recognition, and stride length or walking distance estimation.
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