Abstract
Human learners acquire complex interconnected networks of relational knowledge. The capacity for such learning naturally depends on two factors: the architecture (or informational structure) of the knowledge network itself and the architecture of the computational unit—the brain—that encodes and processes the information. That is, learning is reliant on integrated network architectures at two levels: the epistemic and the computational, or the conceptual and the neural. Motivated by a wish to understand conventional human knowledge, here, we discuss emerging work assessing network constraints on the learnability of relational knowledge, and theories from statistical physics that instantiate the principles of thermodynamics and information theory to offer an explanatory model for such constraints. We then highlight similarities between those constraints on the learnability of relational networks, at one level, and the physical constraints on the development of interconnected patterns in neural systems, at another level, both leading to hierarchically modular networks. To support our discussion of these similarities, we employ an operational distinction between the modeller (e.g. the human brain), the model (e.g. a single human’s knowledge) and the modelled (e.g. the information present in our experiences). We then turn to a philosophical discussion of whether and how we can extend our observations to a claim regarding explanation and mechanism for knowledge acquisition. What relation between hierarchical networks, at the conceptual and neural levels, best facilitate learning? Are the architectures of optimally learnable networks a topological reflection of the architectures of comparably developed neural networks? Finally, we contribute to a unified approach to hierarchies and levels in biological networks by proposing several epistemological norms for analysing the computational brain and social epistemes, and for developing pedagogical principles conducive to curious thought.This article is part of the theme issue ‘Unifying the essential concepts of biological networks: biological insights and philosophical foundations’.
Highlights
The human mind is equipped with rich materials and diverse strategies with which to interpret flows of information into structured units and relations [1,2]
Over the past decade or more, the study of the network architecture of neural circuits has been formalized in the field of network neuroscience [22], which draws on graph theory, statistical mechanics and network science to create and study network models of neural systems [23,24,25]
Non-artificial features of human behaviour, we turn to the question of exactly how humans build models of their world. While this question has been asked in different ways for millenia [48], and from within the discipline of psychology for decades [1,2], here we focus on the specific question of how humans perceive relational knowledge, building models of network architectures explaining transition probabilities of sequentially experienced stimuli
Summary
The human mind is equipped with rich materials and diverse strategies with which to interpret flows of information into structured units and relations [1,2]. Over the past decade or more, the study of the network architecture of neural circuits has been formalized in the field of network neuroscience [22], which draws on graph theory, statistical mechanics and network science to create and study network models of neural systems [23,24,25] In some ways, this appreciation of the brain as a networked system is new, in its formal mathematical nature; yet in other ways, this appreciation is a remembrance of what we have speculated about for almost two centuries since Schwann’s proposal in 1839 [26], and known decisively for more than one century as the Neuron Doctrine [27]. In 1906, Cajal and Golgi were awarded the Nobel Prize for Physiology or Medicine for their demonstrative experiments confirming that nerve cells are the discrete units that make up brain tissue, and that they comprise a connected network system by discrete sites of contact We pause at this juncture in the ever-vigorous progress of scientific and philosophical investigation into the nature of mind and reality. What we provide is a review of extant literatures, selected for their relevance and insight into the network architectures supporting learnability, upon which future experimental and theoretical analyses might be built
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
