Needles in a Haystack: Plan Recognition in Large Spatial Domains Involving Multiple Agents

While plan recognition research has been applied to a wide variety of problems, it has largely made identical assumptions about the number of agents participating in the plan, the observability of the plan execution process, and the scale of the domain. We describe a method for plan recognition in a real-world domain involving large numbers of agents performing spatial maneuvers in concert under conditions of limited observability. These assumptions differ radically from those traditionally made in plan recognition and produce a problem which combines aspects of the fields of plan recognition, pattern recognition, and object tracking. We describe our initial solution which borrows and builds upon research from each of these areas, employing a pattern-directed approach to recognize individual movements and generalizing these to produce inferences of large-scale behavior.

[1]  Eliseo Clementini,et al.  Qualitative Representation of Positional Information , 1997, Artif. Intell..

[2]  Annika Waern,et al.  Recognising Human Plans: Issues for Plan Recognition in Human - Computer Interaction , 1996 .

[3]  Edmund H. Durfee,et al.  Deciding When to Commit to Action During Observation-Based Coordination , 1995, ICMAS.

[4]  Jean-François Delannoy,et al.  XPLANS: Case-based reasoning for plan recognition , 1994, Appl. Artif. Intell..

[5]  Bernd Neumann,et al.  Understanding object motion: Recognition, learning and spatiotemporal reasoning , 1991, Robotics Auton. Syst..

[6]  Mark Gahegan,et al.  Proximity Operators for Qualitative Spatial Reasoning , 1995, COSIT.

[7]  Daniel Hernández,et al.  Qualitative Representation of Spatial Knowledge , 1994, Lecture Notes in Computer Science.

[8]  Milind Tambe Recursive Agent and Agent-Group Tracking in a Real-Time Dynamic Environment , 1995, ICMAS.

[9]  Donald A. Waterman,et al.  Pattern-Directed Inference Systems , 1981, IEEE Transactions on Pattern Analysis and Machine Intelligence.

[10]  Hilary Buxton,et al.  Analogical Representation of Spatial Events for Understanding Traffic Behaviour , 1992, ECAI.

[11]  Qiang Yang,et al.  Program understanding as constraint satisfaction , 1995, Proceedings of 2nd Working Conference on Reverse Engineering.

[12]  James F. Allen Temporal reasoning and planning , 1991 .

[13]  Ashwin Ram,et al.  Situation development in a complex real-world domain , 1997 .