Emergent Communication for Numerical Concepts Generalization

Authors

  • Enshuai Zhou University of Science and Technology of China State Key Lab of Processors, Institute of Computing Technology, CAS Cambricon Technologies
  • Yifan Hao State Key Lab of Processors, Institute of Computing Technology, CAS
  • Rui Zhang State Key Lab of Processors, Institute of Computing Technology, CAS
  • Yuxuan Guo University of Science and Technology of China State Key Lab of Processors, Institute of Computing Technology, CAS Cambricon Technologies
  • Zidong Du State Key Lab of Processors, Institute of Computing Technology, CAS Shanghai Innovation Center for Processor Technologies
  • Xishan Zhang State Key Lab of Processors, Institute of Computing Technology, CAS Cambricon Technologies
  • Xinkai Song State Key Lab of Processors, Institute of Computing Technology, CAS
  • Chao Wang University of Science and Technology of China
  • Xuehai Zhou University of Science and Technology of China
  • Jiaming Guo State Key Lab of Processors, Institute of Computing Technology, CAS
  • Qi Yi University of Science and Technology of China State Key Lab of Processors, Institute of Computing Technology, CAS Cambricon Technologies
  • Shaohui Peng Intelligent Software Research Center, Institute of Software, CAS
  • Di Huang State Key Lab of Processors, Institute of Computing Technology, CAS
  • Ruizhi Chen Intelligent Software Research Center, Institute of Software, CAS
  • Qi Guo State Key Lab of Processors, Institute of Computing Technology, CAS
  • Yunji Chen State Key Lab of Processors, Institute of Computing Technology, CAS University of Chinese Academy of Sciences

DOI:

https://doi.org/10.1609/aaai.v38i16.29712

Keywords:

MAS: Agent-Based Simulation and Emergent Behavior, MAS: Agent Communication, ML: Representation Learning, MAS: Coordination and Collaboration, ML: Unsupervised & Self-Supervised Learning, MAS: Distributed Problem Solving

Abstract

Research on emergent communication has recently gained significant traction as a promising avenue for the linguistic community to unravel human language's origins and explore artificial intelligence's generalization capabilities. Current research has predominantly concentrated on recognizing qualitative patterns of object attributes(e.g., shape and color) and paid little attention to the quantitative relationship among object quantities which is known as the part of numerical concepts. The ability to generalize numerical concepts, i.e., counting and calculations with unseen quantities, is essential, as it mirrors humans' foundational abstract reasoning abilities. In this work, we introduce the NumGame, leveraging the referential game framework, forcing agents to communicate and generalize the numerical concepts effectively. Inspired by the human learning process of numbers, we present a two-stage training approach that sequentially fosters a rudimentary numerical sense followed by the ability of arithmetic calculation, ultimately aiding agents in generating semantically stable and unambiguous language for numerical concepts. The experimental results indicate the impressive generalization capabilities to unseen quantities and regularity of the language emergence from communication.
AAAI-24 / IAAI-24 / EAAI-24 Proceedings Cover

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Published

2024-03-24

How to Cite

Zhou, E., Hao, Y., Zhang, R., Guo, Y., Du, Z., Zhang, X., … Chen, Y. (2024). Emergent Communication for Numerical Concepts Generalization. Proceedings of the AAAI Conference on Artificial Intelligence, 38(16), 17609–17617. https://doi.org/10.1609/aaai.v38i16.29712

Issue

Vol. 38 No. 16: AAAI-24 Technical Tracks 16

Section

AAAI Technical Track on Multiagent Systems