Jes Parent

Embodied & Diverse Intelligences: Development, Learning & Evolution across Biological, Cognitive, and Artificial Domains


Curriculum vitae


jeparent [@] ucsd.edu


1. Halıcıoğlu Data Science Institute, UCSD, San Diego CA

2. Cognition Futures, OREL, Boston MA



Meta-brain Models: biologically-inspired cognitive agents


Journal article


Bradly Alicea, Jesse Parent
IOP Conference Series: Materials Science and Engineering, 2021

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APA   Click to copy
Alicea, B., & Parent, J. (2021). Meta-brain Models: biologically-inspired cognitive agents. IOP Conference Series: Materials Science and Engineering.


Chicago/Turabian   Click to copy
Alicea, Bradly, and Jesse Parent. “Meta-Brain Models: Biologically-Inspired Cognitive Agents.” IOP Conference Series: Materials Science and Engineering (2021).


MLA   Click to copy
Alicea, Bradly, and Jesse Parent. “Meta-Brain Models: Biologically-Inspired Cognitive Agents.” IOP Conference Series: Materials Science and Engineering, 2021.


BibTeX   Click to copy

@article{bradly2021a,
  title = {Meta-brain Models: biologically-inspired cognitive agents},
  year = {2021},
  journal = {IOP Conference Series: Materials Science and Engineering},
  author = {Alicea, Bradly and Parent, Jesse}
}

Abstract

Artificial Intelligence (AI) systems based solely on neural networks or symbolic computation present a representational complexity challenge. While minimal representations can produce behavioral outputs like locomotion or simple decision-making, more elaborate internal representations might offer a richer variety of behaviors. We propose that these issues can be addressed with a computational approach we call meta-brain models. Meta-brain models are embodied hybrid models that include layered components featuring varying degrees of representational complexity. We will propose combinations of layers composed using specialized types of models. Rather than using a generic black box approach to unify each component, this relationship mimics systems like the neocortical-thalamic system relationship of the mammalian brain, which utilizes both feedforward and feedback connectivity to facilitate functional communication. Importantly, the relationship between layers can be made anatomically explicit. This allows for structural specificity that can be incorporated into the model's function in interesting ways. We will propose several types of layers that might be functionally integrated into agents that perform unique types of tasks, from agents that simultaneously perform morphogenesis and perception, to agents that undergo morphogenesis and the acquisition of conceptual representations simultaneously. Our approach to meta-brain models involves creating models with different degrees of representational complexity, creating a layered meta-architecture that mimics the structural and functional heterogeneity of biological brains, and an input/output methodology flexible enough to accommodate cognitive functions, social interactions, and adaptive behaviors more generally. We will conclude by proposing next steps in the development of this flexible and open-source approach.