ResKACNNet: A Residual ChebyKAN Network for Inertial Odometry

Abstract: Inertial Measurement Unit (IMU) has become a key technology for achieving low-cost and precise positioning. However, traditional CNN-based inertial positioning methods struggle to capture the nonlinear motion characteristics and long-term dependencies in IMU data. To address this limitation, we propose a novel inertial positioning network with a generic backbone called ResChebyKAN, which leverages the nonlinear approximation capabilities of Chebyshev polynomials to model complex motion patterns. Additionally, we introduce an Efficient Kernel-based Self-Attention (EKSA) module to effectively capture contextual information and enhance long-term dependency modeling. Experimental results on public datasets (e.g., RIDI, RoNIN, RNIN-VIO, OxIOD, IMUNet, and TLIO) demonstrate that our method reduces the absolute trajectory error by 3.79% to 42.32% compared to existing benchmark methods. Furthermore, we release a preprocessed dataset and empirically show that removing the gravity component from acceleration data significantly improves inertial positioning performance.