The local circuitry of the mammalian brain is a focus of the search for generic computational principles because it is largely conserved across species and modalities. In 2014 a model was proposed representing all neurons and synapses of the stereotypical cortical microcircuit below 1mm2 of brain surface. The model reproduces fundamental features of brain activity but its impact remained limited because of its computational demands. For theory and simulation, however, the model was a breakthrough because it removes uncertainties of downscaling, and larger models are less densely connected. This sparked a race in the neuromorphic computing community and the model became a de facto standard benchmark. Within a few years real-time performance was reached and surpassed at significantly reduced energy consumption. We review how the computational challenge was tackled by different simulation technologies and derive guidelines for the next generation of benchmarks and other domains of science.
@article{arxiv.2505.21185,
title = {Constructive community race: full-density spiking neural network model drives neuromorphic computing},
author = {Johanna Senk and Anno C. Kurth and Steve Furber and Tobias Gemmeke and Bruno Golosio and Arne Heittmann and James C. Knight and Eric Müller and Tobias Noll and Thomas Nowotny and Gorka Peraza Coppola and Luca Peres and Oliver Rhodes and Andrew Rowley and Johannes Schemmel and Tim Stadtmann and Tom Tetzlaff and Gianmarco Tiddia and Sacha J. van Albada and José Villamar and Markus Diesmann},
journal= {arXiv preprint arXiv:2505.21185},
year = {2026}
}