English

A roadmap to reverse engineering real-world generalization by combining naturalistic paradigms, deep sampling, and predictive computational models

Neurons and Cognition 2022-01-17 v2

Abstract

Real-world generalization, e.g., deciding to approach a never-seen-before animal, relies on contextual information as well as previous experiences. Such a seemingly easy behavioral choice requires the interplay of multiple neural mechanisms, from integrative encoding to category-based inference, weighted differently according to the circumstances. Here, we argue that a comprehensive theory of the neuro-cognitive substrates of real-world generalization will greatly benefit from empirical research with three key elements. First, the ecological validity provided by multimodal, naturalistic paradigms. Second, the model stability afforded by deep sampling. Finally, the statistical rigor granted by predictive modeling and computational controls.

Keywords

Cite

@article{arxiv.2108.10231,
  title  = {A roadmap to reverse engineering real-world generalization by combining naturalistic paradigms, deep sampling, and predictive computational models},
  author = {Peer Herholz and Eddy Fortier and Mariya Toneva and Nicolas Farrugia and Leila Wehbe and Valentina Borghesani},
  journal= {arXiv preprint arXiv:2108.10231},
  year   = {2022}
}
R2 v1 2026-06-24T05:21:03.724Z