Learning Based
Learning-based approaches are revolutionizing various fields by enabling systems to learn complex behaviors and adapt to dynamic environments, primarily aiming to improve efficiency, robustness, and safety. Current research focuses on applying deep reinforcement learning, diffusion models, and Koopman operators to control robots, optimize planning algorithms (like those for pathfinding and task sequencing), and improve the accuracy and efficiency of simulations. These advancements have significant implications for robotics, autonomous systems, and other domains requiring adaptable and intelligent control, offering solutions to challenges in areas such as safe navigation, precise manipulation, and efficient resource allocation.
Papers
Learning Flight Control Systems from Human Demonstrations and Real-Time Uncertainty-Informed Interventions
Prashant Ganesh, J. Humberto Ramos, Vinicius G. Goecks, Jared Paquet, Matthew Longmire, Nicholas R. Waytowich, Kevin Brink
Rethinking Boundary Detection in Deep Learning Models for Medical Image Segmentation
Yi Lin, Dong Zhang, Xiao Fang, Yufan Chen, Kwang-Ting Cheng, Hao Chen
BCEdge: SLO-Aware DNN Inference Services with Adaptive Batching on Edge Platforms
Ziyang Zhang, Huan Li, Yang Zhao, Changyao Lin, Jie Liu
UPPLIED: UAV Path Planning for Inspection through Demonstration
Shyam Sundar Kannan, Vishnunandan L. N. Venkatesh, Revanth Krishna Senthilkumaran, Byung-Cheol Min
A Neurosymbolic Approach to the Verification of Temporal Logic Properties of Learning enabled Control Systems
Navid Hashemi, Bardh Hoxha, Tomoya Yamaguchi, Danil Prokhorov, Geogios Fainekos, Jyotirmoy Deshmukh
DRL-VO: Learning to Navigate Through Crowded Dynamic Scenes Using Velocity Obstacles
Zhanteng Xie, Philip Dames
PlasmoFAB: A Benchmark to Foster Machine Learning for Plasmodium falciparum Protein Antigen Candidate Prediction
Jonas Christian Ditz, Jacqueline Wistuba-Hamprecht, Timo Maier, Rolf Fendel, Nico Pfeifer, Bernhard Reuter