LogicalFactChecker: Leveraging Logical Operations for Fact Checking with Graph Module Network
Abstract
Verifying the correctness of a textual statement requires not only semantic reasoning about the meaning of words, but also symbolic reasoning about logical operations like count, superlative, aggregation, etc. In this work, we propose LogicalFactChecker, a neural network approach capable of leveraging logical operations for fact checking. It achieves the state-of-the-art performance on TABFACT, a large-scale, benchmark dataset built for verifying a textual statement with semi-structured tables. This is achieved by a graph module network built upon the Transformer-based architecture. With a textual statement and a table as the input, LogicalFactChecker automatically derives a program (a.k.a. logical form) of the statement in a semantic parsing manner. A heterogeneous graph is then constructed to capture not only the structures of the table and the program, but also the connections between inputs with different modalities. Such a graph reveals the related contexts of each word in the statement, the table and the program. The graph is used to obtain graph-enhanced contextual representations of words in Transformer-based architecture. After that, a program-driven module network is further introduced to exploit the hierarchical structure of the program, where semantic compositionality is dynamically modeled along the program structure with a set of function-specific modules. Ablation experiments suggest that both the heterogeneous graph and the module network are important to obtain strong results.
Cite
@article{arxiv.2004.13659,
title = {LogicalFactChecker: Leveraging Logical Operations for Fact Checking with Graph Module Network},
author = {Wanjun Zhong and Duyu Tang and Zhangyin Feng and Nan Duan and Ming Zhou and Ming Gong and Linjun Shou and Daxin Jiang and Jiahai Wang and Jian Yin},
journal= {arXiv preprint arXiv:2004.13659},
year = {2020}
}
Comments
13 pages; 7 figures; Accepted by ACL2020 as a long paper