Full State Reconstruction
Full state reconstruction aims to recover complete and accurate representations of systems or objects from incomplete or noisy data. Current research focuses on diverse applications, employing various techniques including neural networks (e.g., UNets, Transformers, diffusion models), implicit neural representations, and spectral graph theory, often tailored to specific data modalities (images, point clouds, time series, etc.). These advancements improve accuracy and efficiency in diverse fields, ranging from robotics and computer vision (3D object reconstruction, hand tracking) to medical imaging (CT and MRI reconstruction) and speech processing (efficient speech separation). The resulting improvements in data analysis and system modeling have significant implications for various scientific and engineering disciplines.
Papers
Robust plug-and-play methods for highly accelerated non-Cartesian MRI reconstruction
Pierre-Antoine Comby (MIND, JOLIOT), Benjamin Lapostolle (MIND), Matthieu Terris (MIND), Philippe Ciuciu (MIND, JOLIOT)
GVKF: Gaussian Voxel Kernel Functions for Highly Efficient Surface Reconstruction in Open Scenes
Gaochao Song, Chong Cheng, Hao Wang
Learned Neural Physics Simulation for Articulated 3D Human Pose Reconstruction
Mykhaylo Andriluka, Baruch Tabanpour, C. Daniel Freeman, Cristian Sminchisescu
Robotic Arm Platform for Multi-View Image Acquisition and 3D Reconstruction in Minimally Invasive Surgery
Alexander Saikia, Chiara Di Vece, Sierra Bonilla, Chloe He, Morenike Magbagbeola, Laurent Mennillo, Tobias Czempiel, Sophia Bano, Danail Stoyanov
Deep unrolled primal dual network for TOF-PET list-mode image reconstruction
Rui Hu, Chenxu Li, Kun Tian, Jianan Cui, Yunmei Chen, Huafeng Liu