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Main Authors: Zhang, Shanshan, Wu, Liqin, Cao, Wenying, Zheng, Lingxiang, Yang, Yu
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.15645
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author Zhang, Shanshan
Wu, Liqin
Cao, Wenying
Zheng, Lingxiang
Yang, Yu
author_facet Zhang, Shanshan
Wu, Liqin
Cao, Wenying
Zheng, Lingxiang
Yang, Yu
contents Pedestrian inertial odometry (PIO) estimates autonomous pedestrian motion using only acceleration and angular velocity measurements collected by an inertial measurement unit (IMU), making it highly valuable for consumer level localization applications. However, under a dual device acquisition setting, IMU signals collected by a freely carried mobile device are inherently composite signals in which the global motion of the human torso is coupled with perturbations induced by local limb motion. This coupling makes accurate human motion modeling more challenging. To address this issue, this paper proposes frequency decomposed inertial odometry (FDIO). The proposed method first decomposes input IMU signals into low frequency and high frequency components using a Laplacian pyramid. It then adopts a Mamba module to model long range motion information from the low frequency component and uses a multi scale convolution module to extract fine grained local dynamic features from the high frequency component. Experiments on five public PIO datasets show that FDIO achieves an average absolute trajectory error of 3.221~m and an average relative trajectory error of 2.550~m, reducing the errors by 33.3\% and 16.7\% compared with the RoNIN ResNet baseline, respectively. These results validate the effectiveness of the proposed frequency decomposition strategy. To the best of our knowledge, this work is among the first efforts to introduce Mamba and a frequency decomposition architecture into inertial odometry.
format Preprint
id arxiv_https___arxiv_org_abs_2511_15645
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle FDIO: Frequency Decomposed Inertial Odometry
Zhang, Shanshan
Wu, Liqin
Cao, Wenying
Zheng, Lingxiang
Yang, Yu
Computer Vision and Pattern Recognition
Robotics
Pedestrian inertial odometry (PIO) estimates autonomous pedestrian motion using only acceleration and angular velocity measurements collected by an inertial measurement unit (IMU), making it highly valuable for consumer level localization applications. However, under a dual device acquisition setting, IMU signals collected by a freely carried mobile device are inherently composite signals in which the global motion of the human torso is coupled with perturbations induced by local limb motion. This coupling makes accurate human motion modeling more challenging. To address this issue, this paper proposes frequency decomposed inertial odometry (FDIO). The proposed method first decomposes input IMU signals into low frequency and high frequency components using a Laplacian pyramid. It then adopts a Mamba module to model long range motion information from the low frequency component and uses a multi scale convolution module to extract fine grained local dynamic features from the high frequency component. Experiments on five public PIO datasets show that FDIO achieves an average absolute trajectory error of 3.221~m and an average relative trajectory error of 2.550~m, reducing the errors by 33.3\% and 16.7\% compared with the RoNIN ResNet baseline, respectively. These results validate the effectiveness of the proposed frequency decomposition strategy. To the best of our knowledge, this work is among the first efforts to introduce Mamba and a frequency decomposition architecture into inertial odometry.
title FDIO: Frequency Decomposed Inertial Odometry
topic Computer Vision and Pattern Recognition
Robotics
url https://arxiv.org/abs/2511.15645