Integrating Visualizations into Modeling NEST Simulations

Integrating Visualizations into Modeling NEST Simulations

Modeling large-scale spiking neural networks showing realistic biological behavior in their dynamics is a complex and tedious task. Since these networks consist of millions of interconnected neurons, their simulation produces an immense amount of data. In recent years it has become possible to simul...

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Bibliographic Details
Published in:Frontiers in neuroinformatics Vol. 9; p. 29
Main Authors: Nowke, Christian, Zielasko, Daniel, Weyers, Benjamin, Peyser, Alexander, Hentschel, Bernd, Kuhlen, Torsten W
Format: Journal Article
Language:English
Published: Switzerland Frontiers Research Foundation 17-12-2015
Frontiers Media S.A
Subjects:
Computer programs
coordinated and multiple views
Data analysis
data management
Firing pattern
interactive visualization
Neural networks
Neuroscience
Neurosciences
Researchers
Semantics
Software
spiking neural network modeling
User interface
Visualization
Workflow integration
Aachen Germany
New York
data management
interactive visualization
spiking neural network modeling
coordinated and multiple views
workflow integration
Online Access:Get full text
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Summary:Modeling large-scale spiking neural networks showing realistic biological behavior in their dynamics is a complex and tedious task. Since these networks consist of millions of interconnected neurons, their simulation produces an immense amount of data. In recent years it has become possible to simulate even larger networks. However, solutions to assist researchers in understanding the simulation's complex emergent behavior by means of visualization are still lacking. While developing tools to partially fill this gap, we encountered the challenge to integrate these tools easily into the neuroscientists' daily workflow. To understand what makes this so challenging, we looked into the workflows of our collaborators and analyzed how they use the visualizations to solve their daily problems. We identified two major issues: first, the analysis process can rapidly change focus which requires to switch the visualization tool that assists in the current problem domain. Second, because of the heterogeneous data that results from simulations, researchers want to relate data to investigate these effectively. Since a monolithic application model, processing and visualizing all data modalities and reflecting all combinations of possible workflows in a holistic way, is most likely impossible to develop and to maintain, a software architecture that offers specialized visualization tools that run simultaneously and can be linked together to reflect the current workflow, is a more feasible approach. To this end, we have developed a software architecture that allows neuroscientists to integrate visualization tools more closely into the modeling tasks. In addition, it forms the basis for semantic linking of different visualizations to reflect the current workflow. In this paper, we present this architecture and substantiate the usefulness of our approach by common use cases we encountered in our collaborative work.
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Reviewed by: Xin Wang, The Salk Institute for Biological Studies, USA; Oliver Schmitt, University of Rostock, Germany
Edited by: Andrew P. Davison, Centre National de la Recherche Scientifique, France
ISSN:1662-5196
1662-5196
DOI:10.3389/fninf.2015.00029