Thursday, September 12, 2024 - 2:00pm
Event Calendar Category
Other LIDS Events
Speaker Name
Eric Cristofalo, PhD, Advanced Capabilities and Systems
Affiliation
MIT Lincoln Laboratory
Building and Room Number
32-D677
Modern military and humanitarian missions require autonomous robots to intelligently reason and act in complex environments. For example, robots in disaster response scenarios must navigate cluttered spaces, locate occluded survivors, and generate a detailed map of the scene for first responders. This is a challenge for today’s robots in part because state-of-the-art robot map representations (e.g., grid maps and dense meshes) do not scale well to large, unstructured environments. Additionally, these maps often only encode structural information required for collision-free navigation, omitting the conceptual information contained in images that could be used for more advanced reasoning or human interpretation.
The Autonomy al Fresco program -- a collaboration between the MIT Lincoln Laboratory and MIT Professors Sertac Karaman and Luca Carlone -- is addressing this conceptual reasoning capability gap by developing autonomy algorithms that leverage 3D scene graph mapping technology. A scene graph is a hierarchical graph where nodes represent concepts in the scene and edges represent the spatial and semantic links between concepts. This talk will overview our real-time scene graph mapping and planning methods designed for robots with resource-constrained compute. We will show recent experiments with a Boston Dynamics Spot quadruped robot to perform open language tasks such as object search.
Eric is a member of the technical staff in the Advanced Capabilities and Systems group at the MIT Lincoln Laboratory. He received his Ph.D. in Aeronautics and Astronautics from Stanford University in 2020, funded in part by a National Defense Science and Engineering Graduate (NDSEG) fellowship. He obtained his M.S. degree in Mechanical Engineering from Boston University and his B.S. degree in Mechanical Engineering from Drexel University.
Eric's research interests include developing advanced autonomy algorithms for camera-equipped, computationally-constrained autonomous robots operating in perception-degraded environments such as rapid disaster response scenarios. He is particularly interested in real-time scene understanding and information-gathering motion planning. His work seeks to field real autonomous platforms in challenging, real-world conditions.