Documentation/Nightly/Extensions/SlicerAstro

From Slicer Wiki
Revision as of 19:45, 31 May 2016 by Davide (talk | contribs)
Jump to: navigation, search
Home < Documentation < Nightly < Extensions < SlicerAstro


For the latest Slicer documentation, visit the read-the-docs.


Kapteyn Astronomical Institute

Introduction and Acknowledgements

Authors: Davide Punzo (Kapteyn Astronomical Institute, University of Groningen), Thijs van der Hulst (Kapteyn Astronomical Institute, University of Groningen), Jos Roerdink (Johann Bernoulli Institute for Mathematics and Computer Science, University of Groningen)
Acknowledgements: Special thanks to Steve Pieper (Isomics), Jean-Christophe Fillion-Robin (Kitware) and Andras Lasso (PerkLab, Queen's).

Contacts:

  • Davide Punzo, <email>punzodavide@hotmail.it</email>; <email>D.Punzo@astro.rug.nl</email>
  • Thijs van der Hulst, <email>J.M.van.der.Hulst@astro.rug.nl</email>
  • Jos Roerdink <email>j.b.t.m.roerdink@rug.nl</email>

Source: [1]
License: Slicer license
Download/install: install 3D Slicer, start 3D Slicer, open the Extension Manager, install the SlicerAstro extension

Extension Description

SlicerAstroIcon1.png

Upcoming HI (neutral Hydrogen) surveys will deliver large datasets, and automated processing using the full 3-D information (two positional dimensions and one spectral dimension) to find and characterize HI objects is imperative. In this context, visualization is an essential tool for enabling qualitative and quantitative human control on an automated source finding and analysis pipeline. Visual Analytics, the combination of automated data processing and human reasoning, creativity and intuition, supported by interactive visualization, enables flexible and fast interaction with the 3-D data, helping the astronomer to deal with the analysis of complex sources. 3-D visualization, coupled to modeling, provides additional capabilities helping the discovery and analysis of subtle structures in the 3-D domain.

Objective: general description

  • 1) proper visualization of astronomical data cubes: using data astronomical data formats, such as FITS, and astronomical world coordinates system (WCS);
  • 2) generation of Histogram, flux density profiles, moment maps and position-velocity diagrams linked with the 3-D view;
  • 3) enabling interactive smoothing in all three dimensions and multiscale analysis, such as wavelet lifting;
  • 4) interactive HI data modeling coupled to visualization;
  • 5) introduction of the SAMP protocol to enable interoperability with Topcat, and other VO tools and catalogs.

Progress (1):

  • FITS reader and AstroVolume done;
  • WCS included in AstroVolume.
  • Added AstroLabelMapVolume (WCS compatible).
  • Generalization of qSlicerUnits.
  • Slicer dataProbe moduile overrided with AstroDataProbe one.
  • First desing of the AstroVolume interface done.
  • Added WCS axis in the 2-D views.
  • Customization of 2-D and 3-D Views.
  • Done!

Progress (3):

  • module created;
  • interface designed;
  • Logic methods implemented on CPU (OpenMP);
  • Logic methods implemented on GPU (OpenGL);
  • Done!

Modules


Use Cases

References

How to cite

Please cite the following paper when referring to SlicerAstro in your publication:

@ARTICLE{2015A&C....12...86P,
   author = {{Punzo}, D. and {van der Hulst}, J.~M. and {Roerdink}, J.~B.~T.~M. and {Oosterloo}, T.~A. and {Ramatsoku}, M. and {Verheijen}, M.~A.~W.},
    title = "{The role of 3-D interactive visualization in blind surveys of H I in galaxies}",
  journal = {Astronomy and Computing},
archivePrefix = "arXiv",
   eprint = {1505.06976},
 primaryClass = "astro-ph.IM",
 keywords = {Radio lines: galaxies, Galaxies: kinematics and dynamics, Surveys, Scientific visualization, Visual analytics},
     year = 2015,
    month = sep,
   volume = 12,
    pages = {86-99},
      doi = {10.1016/j.ascom.2015.05.004},
   adsurl = {http://adsabs.harvard.edu/abs/2015A%26C....12...86P},
  adsnote = {Provided by the SAO/NASA Astrophysics Data System}
}