Abstract

The ocean is vital to all living beings but still needs to be explored, leaving many questions unanswered. Fortunately, underwater robotics has greatly improved ocean exploration by accurately mapping the seafloor in high resolution and tracking animals in midwater. However, these platforms are often too expensive to build and operate, limiting ocean exploration and discovery. To address this issue, we need to lower the barriers to entry, particularly for scientific research requiring high-resolution measurements on a large scale. In this talk, I will share some of the collaborative research work that our team, the CoMPAS lab at MBARI, has been involved in addressing precision control, robust navigation, and machine perception based on novel robotics learning techniques. These are just a few examples of how marine robotics research can help close the ocean exploration gap.

Bio

Giancarlo Troni is a Principal Engineer at the Monterey Bay Aquarium Research Institute (MBARI), where he leads robotics research in the CoMPAS Lab, focusing on the perception, estimation, and control of underwater robotics systems. He has a Ph.D. from Johns Hopkins University and has previously served as an Associate Professor with the Department of Mechanical Engineering, Pontificia Universidad Católica de Chile (PUC), Santiago, Chile. Currently, Giancarlo is dedicated to developing better tools and methods for small, low-cost autonomous machines that can scale ocean exploration.

Abstract

Digital twin (DT) technology is transforming industries by creating digital replicas of physical entities, yet its full potential is hindered by the complexity of modeling and integrating diverse data types. The research focuses on enhancing DT applications through the integration of verification and validation (V&V) with Weighted Flow Matching (WFM). It examines how V&V improves data reliability in rotating mechanical systems and assesses WFM’s role in refining data-driven generative modeling. A meta-learning-based reweighting algorithm (LRW) is introduced to dynamically assign weights to training samples based on their gradient directions, thereby optimizing model robustness against noisy or biased data. Experiments involving rotating machinery and space applications demonstrate improved predictive accuracy, reliable fault diagnosis, and effective system analysis. This integrated approach strengthens DT technology by ensuring more precise system analysis, enhanced model predictive control, and robustness in complex scenarios.

Bio

Yasar Yanik is a  Postdoctoral Researcher in the Dept. of  Applied  Mathematics at  UCSC,   where he leads research on Digital Twin Enabled Autonomous Control for On Orbit Spacecraft Servicing (SURI). His research spans rotating machinery, photovoltaic systems, and spacecraft subsystems, integrating data-driven modeling with physics-based simulations to enhance performance and reliability. He has collaborated with institutions such as Pantex, Sandia National Laboratories, and the Air Force Research Laboratory to advance cutting-edge engineering solutions. Yanik holds a Ph.D. in Mechanical Engineering from Texas Tech University, where he developed high-fidelity digital twin frameworks for predictive diagnostics and health management of energy and mechanical systems.