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9.1 | 1 | (% style="text-align: center;" %) |
| 2 | == Findable. Accessible. User-facing. == | ||
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17.1 | 5 | === Welcome to the single entry point to user-level documentation for EBRAINS tools and services. Here, you can find a list of EBRAINS offerings, sorted by Service Category (SC), and their documentation links. === |
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9.1 | 6 | |
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20.1 | 7 | === Brain atlases === |
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21.1 | 8 | |**[[Atlas-based image segmentation>>url:https://collab.humanbrainproject.eu/#/collab/5401/nav/42067]]** |
| 9 | |**[[HPC workflows for neuroimaging>>url:]]** | ||
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20.1 | 10 | |**[[Interactive Atlas Viewer>>url:https://interactive-viewer.readthedocs.io/en/latest/]]** |
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19.1 | 11 | Interactive Atlas Viewer is a frontend module wrapping around nehuba.It provides additional features, such as metadata integration, data visualisation and a robust plugin system.| |
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21.1 | 12 | |**[[JuGEx>>url:https://www.fz-juelich.de/inm/inm-1/DE/Forschung/_docs/JuGex/JuGex_node.html]]** |
| 13 | JuGEx links cytoarchitecture and gene expression to investigate multilevel human brain organization.|**[[Nutil>>url:https://wiki.ebrains.eu/bin/view/Collabs/quint]]** | ||
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20.1 | 14 | Nutil aims to both simplify and streamline the mechanism of pre-and-post processing 2D brain image data from mouse and rat.|**[[Nutil>>url:https://www.nitrc.org/plugins/mwiki/index.php/nutil:MainPage]]** |
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21.1 | 15 | Nutil aims to both simplify and streamline the mechanism of pre-and-post processing 2D brain image data from mouse and rat.| |
| 16 | |**[[PyJuGex>>url:https://www.fz-juelich.de/inm/inm-1/DE/Forschung/_docs/JuGex/JuGex_node.html]]** | ||
| 17 | JuGEx is an integrated framework of the AllenBrain and JuBrain atlases for statistical analysis of differential gene expression in the adult human brain.|**[[QuickNII>>url:https://www.nitrc.org/docman/?group_id=1341]]** | ||
| 18 | QuickNII is a tool for user guided affine registration (anchoring) of 2D experimental image data, typically high resolution microscopic images, to 3D atlas reference space, facilitating data integration through standardized coordinate systems.|**[[VoluBA>>url:https://voluba-user-doc.apps-dev.hbp.eu/]]** | ||
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20.1 | 19 | volumetric brain anchoring| |
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21.1 | 20 | === Collaboratory === |
| 21 | |**[[Collaboratory>>url:https://wiki.ebrains.eu/bin/view/Collabs/the-collaboratory/]]** | ||
| 22 | Workspaces in the Cloud for your research, development, documentation, and collaboration.=== Data analysis === | ||
| 23 | |**[[Elephant>>url:https://elephant.readthedocs.io/en/v0.6.4/index.html]]** | ||
| 24 | Elephant is an open-source Python library for the analysis of neurophysiology data, using Neo data structures.|**[[Elephant>>url:https://elephant.readthedocs.io/en/latest/index.html]]** | ||
| 25 | Elephant is an open-source Python library for the analysis of neurophysiology data, using Neo data structures.|**[[HBP Validation Framework - Python Client>>url:http://hbp-validation-client.readthedocs.io/]]** | ||
| 26 | A Python package for working with the Human Brain Project Model Validation Framework.| | ||
| 27 | |**[[Neo>>url:https://neo.readthedocs.io/en/stable/]]** | ||
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20.1 | 28 | an object model for handling electrophysiology data in multiple formats.|**[[Neo Viewer>>url:https://neo-viewer.brainsimulation.eu/]]** |
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21.1 | 29 | Django/Angular software for graphing neural activity data (analog signals, spike trains etc.) read from Neo files.|**[[NeuronUntit>>url:]]** |
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20.1 | 30 | | |
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21.1 | 31 | |**[[ViSimpl>>url:https://visimpl-documentation.readthedocs.io/en/latest/]]** |
| 32 | ViSimpl integrates a set of visualization and interaction tools that provide a multi-view visual analysis of brain simultation data.=== Find data === | ||
| 33 | |**[[EBRAINS Knowledge Graph>>url:https://kg.ebrains.eu/]]** | ||
| 34 | A user-driven, data-sharing and data-management infrastructure accelerating scientific progress by providing access to large collections of curated, heterogeneous neuroscience data.=== High-performance computing === | ||
| 35 | |**[[Fenix>>url:https://fenix-ri.eu/about-fenix/documentation]]** | ||
| 36 | Delivering e-infrastructure services federated as the Fenix Infrastructure.|**[[SLURM plugin for the co-allocation of compute and data resources>>url:https://github.com/HumanBrainProject/coallocation-slurm-plugin/blob/master/README.md]]** | ||
| 37 | A plugin for SLURM used for the co-allocation of compute and data resources.|**[[Unicore>>url:https://www.unicore.eu/documentation/]]** | ||
| 38 | A set of software components for federated access to high-performance compute and data resources.| | ||
| 39 | === Medical data analytics === | ||
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20.1 | 40 | |**[[3DViewer>>url:https://meg.univ-amu.fr/wiki/3DViewer]]** |
| 41 | |**[[AnyWave>>url:https://gitlab-dynamap.timone.univ-amu.fr/anywave/anywave/-/wikis/home and https://meg.univ-amu.fr/wiki/AnyWave]]** | ||
| 42 | |**[[Bids Manager & Pipeline>>url:https://github.com/Dynamap/BIDS_Manager]]** | ||
| 43 | Bids Manager is a tool that allows various users to easily import and explore databases in BIDS format. Bids Pipeline, an extension of Bids Manager, allows to launch process on BIDS database.| | ||
| 44 | |**[[Brainstorm>>url:https://neuroimage.usc.edu/brainstorm/Introduction]]** | ||
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21.1 | 45 | |**[[Gardel>>url:]]** |
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20.1 | 46 | |**[[HiBoP>>url:https://collab.humanbrainproject.eu/#/collab/78584/nav/531987?state=uuid%3Df72e40d9-a0bf-4ab7-8a27-462911107c5f]]** |
| 47 | 3D visualization software for intracranial EEG.| | ||
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21.1 | 48 | |**[[ImaGIN>>url:https://f-tract.eu/software/imagin/]]** |
| 49 | |**[[IntrAnat Electrodes>>url:https://f-tract.eu/software/intranat/]]** | ||
| 50 | === Neuromorphic computing === | ||
| 51 | |**[[BrainScaleS>>url:https://flagship.kip.uni-heidelberg.de/jss/FileExchange/D9.7.1_Neuromorphic_Platform_Specification_-_public_version.pdf?fID=1887&s=qqdXDg6HuX3&uID=65]]** | ||
| 52 | Neural network emulation in 1000x accelerated biological real-time.|**[[Neuromorphic Platform Python client>>url:https://electronicvisions.github.io/hbp-sp9-guidebook/]]** | ||
| 53 | Client software for the Human Brain Project Neuromorphic Computing Platform.|**[[SpiNNaker Jupyter Service>>url:http://spinnakermanchester.github.io/common_pages/5.0.0/How_to_use_Jupyter_notebooks_on_SpiNNaker.pdf]]** | ||
| 54 | Jupyter notebook service running next to the SpiNNaker 1Million machine in Manchester.| | ||
| 55 | |**[[SpiNNaker Local Boards>>url:https://spinnakermanchester.github.io/]]** | ||
| 56 | Physical SpiNNaker boards that are loaned to or owned by individuals or groups, but not connected to the SpiNNaker 1Million machine in Manchester.|**[[SpiNNaker Machine>>url:https://spinnakermanchester.github.io/]]** | ||
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20.1 | 57 | The SpiNNaker 1Million core machine in Manchester consisting of 1200 SpiNNaker boards.|**[[SpiNNaker Remote Access>>url:https://flagship.kip.uni-heidelberg.de/jss/FileExchange/D9.7.1_Neuromorphic_Platform_Specification_-_public_version.pdf?fID=1887&s=qqdXDg6HuX3&uID=65]]** |
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21.1 | 58 | The SpiNNaker batch execution service allowing Neuromorphic Computing Platform jobs to be run on the SpiNNaker 1Million machine in Manchester.| |
| 59 | |**[[SpiNNaker Software>>url:http://spinnakermanchester.github.io/]]** | ||
| 60 | The Software used to compile and execute Neural Networks described in PyNN on SpiNNaker hardware.|**[[SpiNNaker-NRP integration>>url:http://spinnakermanchester.github.io/common_pages/5.0.0/How_to_use_Jupyter_notebooks_on_SpiNNaker.pdf]]** | ||
| 61 | Allows the NRP to use SpiNNaker as a brain for robotic simulations.=== Neurorobotics === | ||
| 62 | |**[[Neurorobotics Platform>>url:https://www.neurorobotics.net/Documentation/nrp/user_manual/index.html]]** | ||
| 63 | The NRP supports closed-loop neuroscience and embodied AI by connecting brains and bodies in simulation.=== Share data === | ||
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20.1 | 64 | |**[[Curation services, access to data>>url:https://wiki.ebrains.eu/bin/view/Collabs/data-curation]]** |
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21.1 | 65 | |**[[KnowledgeSpace>>url:https://knowledge-space.org/documentation]]** |
| 66 | Encyclopedia and open data access portal for neuroscience that serves as a framework where large-scale neuroscience projects can expose their data to the neuroscience community-at-large.|**[[fairgraph>>url:https://fairgraph.readthedocs.io/en/latest/]]** | ||
| 67 | Python API for the Human Brain Project Neural Activity Resource, capable of changing, and working with Metadata| | ||
| 68 | === Simulation === | ||
| 69 | |**[[Arbor>>url:https://arbor.readthedocs.io/en/latest/index.html]]** | ||
| 70 | Arbor is a performance portable library for simulation of large networks of multi-compartment neurons on hybrid/accelerated/many core computer architectures.|**[[Arbor>>url:https://arbor.readthedocs.io/en/v0.5/]]** | ||
| 71 | Arbor is a library for implementing performance portable network simulations of multi-compartment neuron models.|**[[BluePyMM>>url:https://bluepymm.readthedocs.io/en/latest/index.html]]** | ||
| 72 | Model Management Python Library| | ||
| 73 | |**[[BluePyOpt>>url:https://bluepyopt.readthedocs.io/en/latest/]]** | ||
| 74 | BluePyOpt is an extensible framework for data-driven model parameter optimisation that wraps and standardizes several existing open-source tools.|**[[CoreNeuron>>url:https://github.com/BlueBrain/CoreNeuron]]** | ||
| 75 | CoreNeuron implements the core functionalities of the NEURON simulator targeting high efficiency when using millions of threads.|**[[Hodgkin Huxley Neuron Builder>>url:https://humanbrainproject.github.io/hbp-sp6-guidebook/online_usecases/single_cell_building/hippocampus/p1_hh_neuron_builder/p1_hh_neuron_builder.html]]** | ||
| 76 | The Hodgkin-Huxley Neuron Builder web-application is a use case that allows the user to interactively go through the entire single cell model building pipeline.| | ||
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20.1 | 77 | |**[[LFPy>>url:https://lfpy.readthedocs.io]]** |
| 78 | |**[[Multi-scale brain simulation with TVB-NEST>>url:https://github.com/the-virtual-brain/tvb-multiscale/tree/master/docs]]** | ||
| 79 | Simulate multi-scale brain network models with TVB and NEST.|**[[NEST>>url:https://nest-simulator.readthedocs.io/en/v2.20.0/]]** | ||
| 80 | NEST is a simulator for spiking neural network models that focuses on the dynamics, size and structure of neural systems rather than on the exact morphology of individual neurons| | ||
| 81 | |**[[NEST Desktop>>url:https://nest-desktop.readthedocs.io]]** | ||
| 82 | A web-based GUI application for NEST simulator|**[[NEST Desktop>>url:https://nest-desktop.readthedocs.io]]** | ||
| 83 | A web-based GUI application for NEST simulator.|**[[NESTML>>url:https://nestml.readthedocs.io/en/latest/]]** | ||
| 84 | A domain specific language to describe neuron models in NEST.| | ||
| 85 | |**[[NEURON>>url:https://www.neuron.yale.edu/neuron/docs]]** | ||
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21.1 | 86 | Simulation enviroment for building and using computational models of neurons and networks of neurons|**[[NeuroM>>url:https://neurom.readthedocs.io/en/v1.4.17/]]** |
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20.1 | 87 | NeuroM is a Python toolkit for the analysis and processing of neuron morphologies.|**[[NeuroScheme>>url:https://neuroscheme-documentation.readthedocs.io/en/latest/]]** |
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21.1 | 88 | NeuroScheme is a tool for navigating, exploring, creating and interacting with NeuroScience data using abstract, schematic or expressive representations.| |
| 89 | |**[[NeuroTessMesh>>url:https://neurotessmesh-documentation.readthedocs.io/en/latest/]]** | ||
| 90 | A Tool for the Generation and Visualization of Neuron Meshes and Adaptive On-the-Fly Refinement|**[[PyNN>>url:http://neuralensemble.org/docs/PyNN/]]** | ||
| 91 | A Python package for simulator-independent specification of neuronal network models.|**[[Snudda>>url:Guidebook: https://collab.humanbrainproject.eu/#/collab/1655/nav/18580]]** | ||
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20.1 | 92 | | |
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21.1 | 93 | |**[[TVB Brain Atlas Viewer>>url:None]]** |
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20.1 | 94 | An interactive viewer of human brain function.|**[[TVB image processing pipeline>>url:/]]** |
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21.1 | 95 | This pipeline combines the BIDS Apps mrtrix3_connectome, fmriprep and tvb_converter into a neuroimaging pipeline to compute structural and functional connectomes from MRI data.|**[[TVB-HPC>>url:https://github.com/the-virtual-brain/tvb-hpc/tree/master/docs]]** |
| 96 | This is a Python package for generating code for parameter sweeps and Bayesian inversion.| | ||
| 97 | |**[[The Virtual Brain>>url:http://docs.thevirtualbrain.org/index.html]]** | ||
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20.1 | 98 | "The Virtual Brain" Project (TVB Project) has the purpose of offering modern tools to the Neurosciences community, for computing, simulating and analyzing functional and structural data of human brains, brains modeled at the level of population of neurons.|**[[The Virtual Brain Web-App>>url:http://docs.thevirtualbrain.org/]]** |
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21.1 | 99 | The Virtual Brain Web App at HBP. |
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12.1 | 100 | |
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9.1 | 101 | === Support === |
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| 103 | In SGA3, the High Level Support Team (HLST, T4.13) is responsible for coordinating documentation efforts in EBRAINS. Contact the [[HLST>>https://ebrains.eu/support/]] if you have questions about this page or our tools, services and workflows. |