Score-Based Learning of Graphical Event Models with Background Knowledge Augmentation

Authors

  • Debarun Bhattacharjya IBM T. J. Watson Research Center
  • Tian Gao IBM T. J. Watson Research Center
  • Dharmashankar Subramanian IBM T. J. Watson Research Center
  • Xiao Shou Rensselaer Polytechnic Institute

DOI:

https://doi.org/10.1609/aaai.v37i10.26437

Keywords:

RU: Graphical Model, DMKM: Mining of Spatial, Temporal or Spatio-Temporal Data, ML: Bayesian Learning, ML: Graph-based Machine Learning, ML: Time-Series/Data Streams

Abstract

Graphical event models (GEMs) are representations of temporal point process dynamics between different event types. Many real-world applications however involve limited event stream data, making it challenging to learn GEMs from data alone. In this paper, we introduce approaches that can work together in a score-based learning paradigm, to augment data with potentially different types of background knowledge. We propose novel scores for learning an important parametric class of GEMs; in particular, we propose a Bayesian score for leveraging prior information as well as a more practical simplification that involves fewer parameters, analogous to Bayesian networks. We also introduce a framework for incorporating easily assessed qualitative background knowledge from domain experts, in the form of statements such as `event X depends on event Y' or `event Y makes event X more likely'. The proposed framework has Bayesian interpretations and can be deployed by any score-based learner. Through an extensive empirical investigation, we demonstrate the practical benefits of background knowledge augmentation while learning GEMs for applications in the low-data regime.

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Published

2023-06-26

How to Cite

Bhattacharjya, D., Gao, T., Subramanian, D., & Shou, X. (2023). Score-Based Learning of Graphical Event Models with Background Knowledge Augmentation. Proceedings of the AAAI Conference on Artificial Intelligence, 37(10), 12189-12197. https://doi.org/10.1609/aaai.v37i10.26437

Issue

Section

AAAI Technical Track on Reasoning Under Uncertainty