New Characterization
Characterizing complex systems and phenomena is a central theme across diverse scientific fields, aiming to understand their underlying structure and behavior. Current research focuses on developing novel methods for characterizing data from various sources, including large language models, molecular dynamics, and sensor networks, often employing machine learning techniques like deep learning and reinforcement learning, as well as classical methods like compressed sensing and topological data analysis. These characterizations are crucial for improving model performance, mitigating biases, enhancing system robustness, and enabling more efficient and effective applications in areas ranging from healthcare and robotics to environmental monitoring and AI safety.
Papers
A Domain-Agnostic Approach for Characterization of Lifelong Learning Systems
Megan M. Baker, Alexander New, Mario Aguilar-Simon, Ziad Al-Halah, Sébastien M. R. Arnold, Ese Ben-Iwhiwhu, Andrew P. Brna, Ethan Brooks, Ryan C. Brown, Zachary Daniels, Anurag Daram, Fabien Delattre, Ryan Dellana, Eric Eaton, Haotian Fu, Kristen Grauman, Jesse Hostetler, Shariq Iqbal, Cassandra Kent, Nicholas Ketz, Soheil Kolouri, George Konidaris, Dhireesha Kudithipudi, Erik Learned-Miller, Seungwon Lee, Michael L. Littman, Sandeep Madireddy, Jorge A. Mendez, Eric Q. Nguyen, Christine D. Piatko, Praveen K. Pilly, Aswin Raghavan, Abrar Rahman, Santhosh Kumar Ramakrishnan, Neale Ratzlaff, Andrea Soltoggio, Peter Stone, Indranil Sur, Zhipeng Tang, Saket Tiwari, Kyle Vedder, Felix Wang, Zifan Xu, Angel Yanguas-Gil, Harel Yedidsion, Shangqun Yu, Gautam K. Vallabha
Three-dimensional reconstruction and characterization of bladder deformations
Augustin C. Ogier, Stanislas Rapacchi, Marc-Emmanuel Bellemare