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    An Ensemble Learning and Problem Solving Architecture for Airspace Management

    Author
    Zhang, Xiaoqin; Yoon, Sungwook; DiBona, Phillip; Appling, Darren; Ding, Li; Doppa, Janardhan; Green, Derek; Guo, Jinhong; Kuter, Ugur; Levine, Geoff; MacTavish, Reid; McFarlane, Daniel; Michaelis, James; Mostafa, Hala; Ontanon, Santiago; Parker, Charles; Radhakrishnan, Jainarayan; Rebguns, Anton; Shrestha, Bhavesh; Song, Zhexuan; Trewhitt, Ethan; Zafar, Huzaifa; Zhang, Chongjie; Corkill, Daniel; DeJong, Gerald; Dietterich, Thomas; Kambhampati, Subbarao; Lesser, Victor; McGuinness, Deborah; Ram, Ashwin; Spears, Diana; Tadepalli, Prasad; Whitaker, Elizabeth; Wong, Weng-Keen; Hendler, Jim; Hofmann, Martin; Whitebread, Kenneth
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    Date Issued
    2011-11-15
    Subject
    Inference Web
    Degree
    Terms of Use
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    URI
    https://hdl.handle.net/20.500.13015/4578
    Abstract
    We present a novel ensemble architecture for learning problem-solving techniques from a very small number of expert solutions and demonstrate its effectiveness in a complex real-world domain. The key feature of our “Generalized Integrated Learning Architecture” (GILA) is a set of heterogeneous independent learning and reasoning (ILR) components, coordinated by a central meta-reasoning executive (MRE). The ILRs are weakly coupled in the sense that all coordination during learning and performance happens through the MRE. Each ILR learns independently from a small number of expert demonstrations of a complex task. During performance, each ILR proposes partial solutions to subproblems posed by the MRE, which are then selected from and pieced together by the MRE to produce a complete solution. The heterogeneity of the learner-reasoners allows both learning and problem solving to be more effective because their abilities and biases are complementary and synergistic. We describe the application of this novel learning and problem solving architecture to the domain of airspace management, where multiple requests for the use of airspaces need to be deconflicted, reconciled and managed automatically. Formal evaluations show that our system performs as well as or better than humans after learning from the same training data. Furthermore, GILA outperforms any individual ILR run in isolation, thus demonstrating the power of the ensemble architecture for learning and problem solving.;
    Department
    Publisher
    Transactions on Intelligent Systems and Technology
    Relationships
    https://tw.rpi.edu/project/InferenceWeb;
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