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Auteurs principaux: Vogginger, Bernhard, Thanasoulis, Vasilis, Partzsch, Johannes, Mayr, Christian
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2603.24854
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author Vogginger, Bernhard
Thanasoulis, Vasilis
Partzsch, Johannes
Mayr, Christian
author_facet Vogginger, Bernhard
Thanasoulis, Vasilis
Partzsch, Johannes
Mayr, Christian
contents Neuromorphic VLSI systems take inspiration from biology to enable efficient emulation of large-scale spiking neural networks and to explore new computational paradigms. To establish large neuromorphic systems, a sophisticated routing infrastructure is needed to communicate spikes between chips and to/from the host computer. For the BrainScaleS wafer-scale neuromorphic system considered in this work, especially the stimulation with input spikes and the recording of spikes is demanding, requiring high bandwidth and temporal resolution due to the accelerated emulation of neural dynamics 10.000 faster than biological real time. Here, we present a systematic characterization of the BrainScaleS off-wafer communication infrastructure implemented around Kintex7 FPGAs. The communication flow is characterized in terms of throughput, transmission delay, jitter and pulse loss. Further, we analyze the effect of the communication distortions (like pulse loss and jitter) on a neural benchmark model with highly varying spike activity. The presented methods and techniques for communication evaluation are general applicable and provide useful insights for the mapping of network models to the hardware such as the distribution of input spikes across communication channels.
format Preprint
id arxiv_https___arxiv_org_abs_2603_24854
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Characterization of Off-wafer Pulse Communication in BrainScaleS Neuromorphic System
Vogginger, Bernhard
Thanasoulis, Vasilis
Partzsch, Johannes
Mayr, Christian
Emerging Technologies
Hardware Architecture
Neuromorphic VLSI systems take inspiration from biology to enable efficient emulation of large-scale spiking neural networks and to explore new computational paradigms. To establish large neuromorphic systems, a sophisticated routing infrastructure is needed to communicate spikes between chips and to/from the host computer. For the BrainScaleS wafer-scale neuromorphic system considered in this work, especially the stimulation with input spikes and the recording of spikes is demanding, requiring high bandwidth and temporal resolution due to the accelerated emulation of neural dynamics 10.000 faster than biological real time. Here, we present a systematic characterization of the BrainScaleS off-wafer communication infrastructure implemented around Kintex7 FPGAs. The communication flow is characterized in terms of throughput, transmission delay, jitter and pulse loss. Further, we analyze the effect of the communication distortions (like pulse loss and jitter) on a neural benchmark model with highly varying spike activity. The presented methods and techniques for communication evaluation are general applicable and provide useful insights for the mapping of network models to the hardware such as the distribution of input spikes across communication channels.
title Characterization of Off-wafer Pulse Communication in BrainScaleS Neuromorphic System
topic Emerging Technologies
Hardware Architecture
url https://arxiv.org/abs/2603.24854