Inertial Measurement Unit
Inertial Measurement Units (IMUs) are small, self-contained sensors that measure acceleration and angular velocity, providing crucial data for motion tracking and localization across diverse applications. Current research focuses on improving IMU data processing through advanced algorithms like Kalman filters, recurrent neural networks (RNNs), transformers, and novel approaches leveraging data augmentation and equivariant neural networks to enhance accuracy and robustness, particularly in challenging environments or with limited data. These advancements are driving significant improvements in areas such as human activity recognition, visual-inertial odometry, and pose estimation, with implications for fields ranging from healthcare and fitness to robotics and autonomous navigation. The development of efficient calibration techniques and the exploration of sensor fusion with other modalities, like cameras and UWB, are also key areas of ongoing investigation.
Papers
Enhancing Inertial Hand based HAR through Joint Representation of Language, Pose and Synthetic IMUs
Vitor Fortes Rey, Lala Shakti Swarup Ray, Xia Qingxin, Kaishun Wu, Paul Lukowicz
FLOW: Fusing and Shuffling Global and Local Views for Cross-User Human Activity Recognition with IMUs
Qi Qiu, Tao Zhu, Furong Duan, Kevin I-Kai Wang, Liming Chen, Mingxing Nie, Mingxing Nie
Visual-inertial state estimation based on Chebyshev polynomial optimization
Hongyu Zhang, Maoran Zhu, Qi Cai, Yuanxin Wu
MM3DGS SLAM: Multi-modal 3D Gaussian Splatting for SLAM Using Vision, Depth, and Inertial Measurements
Lisong C. Sun, Neel P. Bhatt, Jonathan C. Liu, Zhiwen Fan, Zhangyang Wang, Todd E. Humphreys, Ufuk Topcu
Gyro-based Neural Single Image Deblurring
Heemin Yang, Jaesung Rim, Seungyong Lee, Seung-Hwan Baek, Sunghyun Cho