PLoS Computational Biology (Apr 2024)

Emergent neural dynamics and geometry for generalization in a transitive inference task.

  • Kenneth Kay,
  • Natalie Biderman,
  • Ramin Khajeh,
  • Manuel Beiran,
  • Christopher J Cueva,
  • Daphna Shohamy,
  • Greg Jensen,
  • Xue-Xin Wei,
  • Vincent P Ferrera,
  • L F Abbott

DOI
https://doi.org/10.1371/journal.pcbi.1011954
Journal volume & issue
Vol. 20, no. 4
p. e1011954

Abstract

Read online

Relational cognition-the ability to infer relationships that generalize to novel combinations of objects-is fundamental to human and animal intelligence. Despite this importance, it remains unclear how relational cognition is implemented in the brain due in part to a lack of hypotheses and predictions at the levels of collective neural activity and behavior. Here we discovered, analyzed, and experimentally tested neural networks (NNs) that perform transitive inference (TI), a classic relational task (if A > B and B > C, then A > C). We found NNs that (i) generalized perfectly, despite lacking overt transitive structure prior to training, (ii) generalized when the task required working memory (WM), a capacity thought to be essential to inference in the brain, (iii) emergently expressed behaviors long observed in living subjects, in addition to a novel order-dependent behavior, and (iv) expressed different task solutions yielding alternative behavioral and neural predictions. Further, in a large-scale experiment, we found that human subjects performing WM-based TI showed behavior inconsistent with a class of NNs that characteristically expressed an intuitive task solution. These findings provide neural insights into a classical relational ability, with wider implications for how the brain realizes relational cognition.