English

Connectivity Concepts in Neuronal Network Modeling

Neurons and Cognition 2022-09-16 v3

Abstract

Sustainable research on computational models of neuronal networks requires published models to be understandable, reproducible, and extendable. Missing details or ambiguities about mathematical concepts and assumptions, algorithmic implementations, or parameterizations hinder progress. Such flaws are unfortunately frequent and one reason is a lack of readily applicable standards and tools for model description. Our work aims to advance complete and concise descriptions of network connectivity but also to guide the implementation of connection routines in simulation software and neuromorphic hardware systems. We first review models made available by the computational neuroscience community in the repositories ModelDB and Open Source Brain, and investigate the corresponding connectivity structures and their descriptions in both manuscript and code. The review comprises the connectivity of networks with diverse levels of neuroanatomical detail and exposes how connectivity is abstracted in existing description languages and simulator interfaces. We find that a substantial proportion of the published descriptions of connectivity is ambiguous. Based on this review, we derive a set of connectivity concepts for deterministically and probabilistically connected networks and also address networks embedded in metric space. Beside these mathematical and textual guidelines, we propose a unified graphical notation for network diagrams to facilitate an intuitive understanding of network properties. Examples of representative network models demonstrate the practical use of the ideas. We hope that the proposed standardizations will contribute to unambiguous descriptions and reproducible implementations of neuronal network connectivity in computational neuroscience.

Keywords

Cite

@article{arxiv.2110.02883,
  title  = {Connectivity Concepts in Neuronal Network Modeling},
  author = {Johanna Senk and Birgit Kriener and Mikael Djurfeldt and Nicole Voges and Han-Jia Jiang and Lisa Schüttler and Gabriele Gramelsberger and Markus Diesmann and Hans E. Plesser and Sacha J. van Albada},
  journal= {arXiv preprint arXiv:2110.02883},
  year   = {2022}
}
R2 v1 2026-06-24T06:40:35.486Z