Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-23T20:39:42.787Z Has data issue: false hasContentIssue false
  • English
  • Français

Scientific Visualization in Astronomy: Towards the Petascale Astronomy Era

Published online by Cambridge University Press:  02 January 2013

Amr Hassan  and
Christopher J. Fluke
Amr Hassan*
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, PO Box 218, Hawthorn, Vic. 3122, Australia
Christopher J. Fluke
Affiliation:
Centre for Astrophysics and Supercomputing, Swinburne University of Technology, PO Box 218, Hawthorn, Vic. 3122, Australia
*
BCorresponding author. Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Astronomy is entering a new era of discovery, coincident with the establishment of new facilities for observation and simulation that will routinely generate petabytes of data. While an increasing reliance on automated data analysis is anticipated, a critical role will remain for visualization-based knowledge discovery. We have investigated scientific visualization applications in astronomy through an examination of the literature published during the last two decades. We identify the two most active fields for progress — visualization of large-N particle data and spectral data cubes—discuss open areas of research, and introduce a mapping between astronomical sources of data and data representations used in general-purpose visualization tools. We discuss contributions using high-performance computing architectures (e.g. distributed processing and GPUs), collaborative astronomy visualization, the use of workflow systems to store metadata about visualization parameters, and the use of advanced interaction devices. We examine a number of issues that may be limiting the spread of scientific visualization research in astronomy and identify six grand challenges for scientific visualization research in the Petascale Astronomy Era.

Keywords

methods: data analysistechniques: miscellaneous
Type
Research Article
Information
Publications of the Astronomical Society of Australia , Volume 28 , Issue 2 , 2011 , pp. 150 - 170
Copyright
Copyright © Astronomical Society of Australia 2011

References

Ahrens, J., Heitmann, K., Habib, S., Ankeny, L., McCormick, P., Inman, J., Armstrong, R., & Ma, K., 2006, Quantitative and comparative visualization applied to cosmological simulations. In: Journal of Physics: Conference Series. Vol. 46, Institute of Physics Publishing, pp. 526534Google Scholar
Amati, G., Di Rico, G., Melotti, M., Ferro, D., & Paioro, L., 2003, AstroMD: a 3, visualization and analysis tool for astrophysical data. IEEE Transactions on Visualization and Computer Graphics 1, (1)Google Scholar
Arce, H. G., Borkin, M. A., Goodman, A. A., Pineda, J. E., & Halle, M. W., 2010, The COMPLETE Survey of Outows in Perseus. Astrophysical Journal 715, 11701190CrossRefGoogle Scholar
Aschwanden, M., 2010, Image Processing Techniques and Feature Recognition in Solar Physics. Solar Physics, 141Google Scholar
Ball, N., & Brunner, R., 2009, Data mining and machine learning in astronomy. International Journal of Modern Physics, D 1, (17), 153Google Scholar
Barnes, D., Fluke, C., Bourke, P., & Parry, O., 2006, An Advanced, Three-Dimensional Plotting Library for Astronomy. Publications of the Astronomical Society of Australia 2, (2), 8293CrossRefGoogle Scholar
Barrett, P., & Bridgman, W., 2000, PyFITS. a Python FITS Module. In: Astronomical Data Analysis Software and Systems IX. Vol. 216, p. 67Google Scholar
Becciani, U., Antonuccio-Delogu, V., Buonomo, F., & Gheller, C., 2001, An Integrated Procedure for Tree N-body Simulations: FLY and AstroMD. In: Astronomical Data Analysis Software and Systems X. Vol. 238, p. 503Google Scholar
Becciani, U., Antonuccio-Delogu, V., Gheller, C., Calori, L., Buonomo, F., & Imboden, S., 2000, AstroMD. A multi-dimensional data analysis tool for astrophysical simulations. Arxiv preprint astroph/0006402Google Scholar
Becciani, U., Costa, A., Antonuccio-Delogu, V., Caniglia, G., Comparato, M., Gheller, C., Jin, Z., Krokos, M., & Massimino, P., 2010, VisIVO – Integrated Tools and Services for Large-Scale Astrophysical Visualization. Publications of the Astronomical Society of the Pacific 122, 119130Google Scholar
Beeson, B., Barnes, D., & Bourke, P., 2003, A distributed-data implementation of the perspective shear-warp volume rendering algorithm for visualisation of large astronomical cubes. Publications of the Astronomical Society of Australia 20, 300313Google Scholar
Beeson, B., Lancaster, M., Barnes, D., Bourke, P., & Rixon, G., 2004, Visualizing astronomy data using VRML. In: Proceedings of SPIE. Vol. 5493, pp. 242253Google Scholar
Bell, G., Hey, T., & Szalay, A., 2009, Beyond the data deluge. Science 32, (5919), 12971298Google Scholar
Biddiscombe, J., Graham, D., & Maruzewski, P., 2007, Interactive visualization and exploration of SPH data. In: Proceedings of 2nd SPHERIC international workshop, Madrid (Spain)Google Scholar
Bloomenthal, J., 1994, An implicit surface polygonizer. Graphics gems IV 1, 324349CrossRefGoogle Scholar
Booth, R., De Blok, W., Jonas, J., & Fanaroff, B., 2009, MeerKAT Key Project Science, Specifications, and Proposals. Arxiv preprint arXiv:0910.2935Google Scholar
Borkin, M., Arce, H., Goodman, A., & Halle, M., 2008, 3, Visualization and Detection of Outows From Young Stars. In: Argyle, R. W., Bunclark, P. S., & Lewis, J. R. (Eds.), Astronomical Data Analysis Software and Systems XVII. Vol. 39, of Astronomical Society of the Pacific Conference Series. p. 145Google Scholar
Borkin, M., Goodman, A., Halle, M., & Alan, D., 2007, Application of Medical Imaging Software to 3, Visualization of Astronomical Data. In: Astronomical society of the pacific conference series. Vol. 376, p. 621Google Scholar
Borkin, M., Ridge, N., Goodman, A., & Halle, M., 2005, Demonstration of the applicability of 3, Slicer to Astronomical Data Using 13CO and C18, Observations of IC348, Arxiv preprint astro-ph/0506604Google Scholar
Borne, K., 2009, Scientific data mining in astronomy. In: Next Generation of Data Mining. CRC Press, Ch. 5, pp. 91114Google Scholar
Brodbeck, D., Hellinger, D., Nolthenius, R., Primack, J., & Klypin, A., 1998, Visualization of Cold + Hot and Cold Dark Matter Cosmologies versus CfA1 Data. Astrophysical Journal 495, 1Google Scholar
Brown, R., Wild, W., & Cunningham, C., 2004, ALMAthe Atacama large millimeter array. Advances in Space Research 3, (3), 555559Google Scholar
Brugel, E., Domik, G., & Ayres, T., 1993, Visualization techniques to aid in the analysis of multispectral astrophysical data sets. Colorado University ReportGoogle Scholar
Brunner, R. J., Djorgovski, S. G., Prince, T. A., & Szalay, A. S., 2002, Massive datasets in astronomy. In: The Handbook of Massive Datasets. Kluwer Academic Publishers, Ch. 27, pp. 931979Google Scholar
Cabral, B., Cam, N., & Foran, J., 1994, Accelerated volume rendering and tomographic reconstruction using texture mapping hardware. In: Proceedings of the 199, symposium on Volume visualization. ACM, pp. 9198Google Scholar
Colless, M., Dalton, G., Maddox, S., Sutherland, W., Norberg, P., Cole, S., Bland-Hawthorn, J., Bridges, T., Cannon, R., Collins, C., et al. , 2001, The 2df galaxy redshift survey: spectra and redshifts. Monthly Notices of the Royal Astronomical Society 32, (4), 10391063Google Scholar
Comparato, M., Becciani, U., Costa, A., Larsson, B., Garilli, B., Gheller, C., & Taylor, J., 2007, Visualization, exploration, and data analysis of complex astrophysical data. Publications of the Astronomical Society of the Pacific 119, 898913Google Scholar
Correa, C., & Ma, K., 2008, Size-based transfer functions: A new volume exploration technique. IEEE transactions on visualization and computer graphics, 13801387Google Scholar
DeFanti, T., Brown, M., & McCormick, B., 1989, Visualization: Expanding Scientific and Engineering Research Opportunities. Computer, 1225Google Scholar
Djorgovski, S., 2005, Virtual astronomy, information technology, and the new scientific methodology. In: Computer Architecture for Machine Perception, 2005, CAMP 2005, Proceedings. Seventh International Workshop. pp. 125132Google Scholar
Djorgovski, S., & Davis, M., 1987, Fundamental properties of elliptical galaxies. Astrophysical Journal 31, (Part 1)Google Scholar
Djorgovski, S., Hut, P., McMillan, S., Vesperini, E., Knop, R., Farr, W., & Graham, M., 2009, Exploring the Use of Virtual Worlds as a Scientific Research Platform: The Meta-Institute for Computational Astrophysics (MICA). Arxiv preprint arXiv:0907.3520Google Scholar
Dolag, K., Reinecke, M., Gheller, C., & Imboden, S., 2008, Splotch: visualizing cosmological simulations. New Journal of Physics 10, 125006Google Scholar
Domik, G., 1992, Visualization of Multi-dimensional Arrays in Astronomy. In: European Southern Observatory Astrophysics Symposia. Vol. 43, p. 249Google Scholar
Domik, G., Mickus-Miceli, K., 1992, Software Design and Development In a Scientific Environment: Lessons Learned During the Development of STAR, an Astrophysical Analysis and Visualization Package. In: Astronomical Data Analysis Software and Systems I. Vol. 25, p. 95Google Scholar
Draper, P., Allan, A., Berry, D., Currie, M., Giaretta, D., Rankin, S., Gray, N., & Taylor, M., 2005, Starlink Software Developments. In: Astronomical Data Analysis Software and Systems XIV. Vol. 347, p. 22Google Scholar
Draper, P., Berry, D., Jenness, T., Economou, F., & Currie, M., 2008, GAIA-3D: Volume Visualization of Data-Cubes. In: Astronomical Data Analysis Software and Systems XVII. Vol. 394, p. 339Google Scholar
Dubinski, J., 2008, Visualizing astrophysical N-body systems. New Journal of Physics 10, 125002Google Scholar
Emmart, C., Nadeau, D., Genetti, J., & Wesselak, E., 2000, Volume Visualization of the Orion Nebula. In: SIGGRAPH 200, Electronic Theatre, Issue 134, SIGGRAPHGoogle Scholar
Farr, W., Hut, P., Ames, J., & Johnson, A., 2009, An Experiment in Using Virtual Worlds for Scientific Visualization of Self-Gravitating Systems. Journal of Virtual Worlds Research 2, (3)Google Scholar
Fluke, C., Barnes, D., & Jones, N., 2009, Interchanging Interactive 3, Graphics for Astronomy. Publications of the Astronomical Society of Australia 26, 3747Google Scholar
Fluke, C., Bourke, P., & ODonovan, D., 2006, Future Directions in Astronomy Visualization. Publications of the Astronomical Society of Australia 2, (1), 1224Google Scholar
Fomalont, E., 1982, Image Display, Processing and Analysis. In: NRAO/VLA Workshop: Synthesis Mapping: 1982 June 2, p. 11.Google Scholar
Frenkel, K., 1988, The art and science of visualizing data. Communications of the ACM 3, (2), 121Google Scholar
Funkhouser, H., 1936, A note on a tenth century graph. Osiris 1, 260262Google Scholar
Gallagher, R., 1995, Computer Visualization: graphics techniques for scientific and engineering analysis. CRCGoogle Scholar
Geller, M., Falco, E., Fabricant, D., & Estus, B., 1992, Visualizing the universe. In: Proceedings of the 3rd conference on Visualization' 92, IEEE Computer Society Press, pp. 390397Google Scholar
Genetti, J., 2002, Volume-rendered galactic animations. Communications of the ACM 4, (11), 66Google Scholar
Gerstner, T., & Pajarola, R., 2000, Topology preserving and controlled topology simplifying multiresolution isosurface extraction. In: Visualization 2000, Proceedings. pp. 259266Google Scholar
Gheller, C., Buonomo, F., Calori, L., & Becciani, U., 2002, AstroMD and Cosmo. Lab, visualizing astrophysical data. In: Proceedings of Joint Eurographics–IEEE TCVG Symposium on Visualization. pp. 16Google Scholar
Gheller, C., Melotti, M., Calori, L., Becciani, U., & Ferro, D., 2003, The Cosmo. Lab Project: Developing AstroMD, an Object Oriented, Open Source Visualization and Pre-analysis Tool for Astrophysical Data. In: Astronomical Society of the Pacific Conference Series. Vol. 295, ASP, pp. 449452Google Scholar
Gooch, R., 1995a, Astronomers and their shady algorithms. In: IEEE Conference on Visualization, 1995, Visualization '95, Proceedings. pp. 374377Google Scholar
Gooch, R., 1995b, Space and the Spaceball. In: Astronomical Data Analysis Software and Systems IV. Vol. 77, p. 144Google Scholar
Gooch, R., 1996, Karma: a Visualization Test-Bed. In: Astronomical Data Analysis Software and Systems V. Vol. 101, p. 80Google Scholar
Goodman, A., 2009, Seeing Science. Arxiv preprint arXiv:0911.3349Google Scholar
Goodman, A. A., Rosolowsky, E. W., Borkin, M. A., Foster, J. B., Halle, M., Kauffmann, J., & Pineda, J. E., 2009, A role for self-gravity at multiple length scales in the process of star formation. Nature 457, 6366Google Scholar
Greensky, J., Czech, W., Yuen, D., Knox, M., Damon, M., Chen, S., & Kameyama, M., 2008, Ubiquitous interactive visualization of 3, mantle convection using a web-portal with Java and Ajax framework. Visual Geosciences 1, (1), 105115Google Scholar
Hanson, A., Fu, C., Wernert, E., & Frisch, P., 2002, Case Study: Constructing the Solar Journey. PreprintGoogle Scholar
Hassan, A. H., Fluke, C. J., & Barnes, D. G., 2010, Interactive visualization of the largest radioastronomy cubes. New Astronomy 16, 100Google Scholar
Hockney, R., & Eastwood, J., 1988, Computer simulation using particles. Taylor & FrancisGoogle Scholar
Holliman, N., Baugh, C., Frenk, C., Jenkins, A., Froner, B., Hassaine, D., Helly, J., Metcalfe, N., & Okamoto, T., 2006, Cosmic cookery: making a stereoscopic 3, animated movie. In: Proceedings of SPIE. Vol. 6055, 605505Google Scholar
Hopf, M., & Ertl, T., 2003, Hierarchical splatting of scattered data. In: Proceedings of the 14th IEEE Visualization 200 (VIS'03). IEEE Computer Society, p. 57Google Scholar
Hopf, M., Luttenberger, M., & Ertl, T., 2004, Hierarchical Splatting of Scattered 4, Data (HTML). IEEE Computer Graphics and Applications 2, (4)Google Scholar
Hultquist, C., Perumal, S., Marais, P., & Fairall, T., 2003, Large-scale structure in the universe. Tech. Rep. CS03-16-00, Department of Computer Science, University of Cape TownGoogle Scholar
Ireland, J., & Young, C. A., 2009, Solar Image Analysis and Visualization. SpringerGoogle Scholar
Ivezic, Z., Tyson, J., Allsman, R., Andrew, J., Angel, R., Axelrod, T., Barr, J., Becker, A., Becla, J., Beldica, C., et al. , 2008, LSST: from science drivers to reference design and anticipated data products. Arxiv preprint arXiv:0805.2366Google Scholar
Jin, Z., Krokos, M., Rivi, M., Gheller, C., Dolag, K., & Reinecke, M., 2010, High-performance astrophysical visualization using Splotch. ArXiv e-printsGoogle Scholar
Johnson, C., & Hansen, C., 2004, The Visualization Handbook. Academic Press, Inc. Orlando, FL, USAGoogle Scholar
Johnston, S., Taylor, R., Bailes, M., Bartel, N., Baugh, C., Bietenholz, M., Blake, C., Braun, R., Brown, J., Chatterjee, S., et al. , 2008, Science with ASKAP. Experimental Astronomy 22 (3), 151273Google Scholar
Kähler, R., Abel, T., & Hege, H., 2007, Simultaneous GPU-assisted raycasting of unstructured point sets and volumetric grid data. In: Proceedings of IEEE/EG International Symposium on Volume Graphics. pp. 4956Google Scholar
Kähler, R., Cox, D., Patterson, R., Levy, S., Hege, H. C., & Abel, T., 2002, Rendering the first star in the universe: a case study. In: VIS '02, Proceedings of the conference on Visualization '02, IEEE Computer Society, Washington, DC, USA, pp. 537540Google Scholar
Kähler, R., & Hege, H., 2002, Interactive volume rendering of adaptive mesh refinement data. The Visual Computer 1, (8), 481492Google Scholar
Kähler, R., Simon, M., & Hege, H., 2003, Interactive volume rendering of large sparse data sets using adaptive mesh refinement hierarchies. IEEE Transactions on Visualization and Computer Graphics 9, (3), 341351Google Scholar
Kähler, R., Wise, J., Abel, T., & Hege, H., 2006, GPUassisted raycasting for cosmological adaptive mesh refinement simulations. In: Eurographics/IEEE VGTC Workshop on Volume Graphics (Boston, Massachusetts, USA, 2006), Eurographics Association. Citeseer, pp. 103110Google Scholar
Kapferer, W., & Riser, T., 2008, Visualization needs and techniques for astrophysical simulations. New Journal of Physics 10, 125008Google Scholar
Keller, S., Schmidt, B., Bessell, M., Conroy, P., Francis, P., Granlund, A., Kowald, E., Oates, A., Martin-Jones, T., Preston, T., et al. , 2007, The SkyMapper telescope and the southern sky survey. Publications of the Astronomical Society of Australia 2, (1), 112Google Scholar
Kissler-Patig, M., Copin, Y., Ferruit, P., Pécontal-Rousset, A., & Roth, M., 2004, The Euro3, data format: A common FITS data format for integral field spectrographs. Astronomische Nachrichten 32, (2), 159162Google Scholar
Klypin, A., Trujillo-Gomez, S., & Primack, J., 2010, Halos and galaxies in the standard cosmological model: results from the bolshoi simulationGoogle Scholar
Kobbelt, L., & Botsch, M., 2004, A survey of pointbased techniques in computer graphics. Computers & Graphics 2, (6), 801814Google Scholar
Lacroute, P., & Levoy, M., 1994, Fast volume rendering using a shear-warp factorization of the viewing transformation. In: Proceedings of the 21st annual conference on Computer graphics and interactive techniques. ACM, p. 458Google Scholar
Leech, J., & Jenness, T., 2005, A Survey of Software for the Manipulation and Visualization of 3-D Submm Spectral Line Datasets. In: Astronomical Data Analysis Software and Systems XIV. Vol. 347, p. 143Google Scholar
Li, H., Fu, C., & Hanson, A., 2008, Visualizing Multiwavelength Astrophysical Data. IEEE Transactions on Visualization and Computer Graphics 1, (6), 15551562Google Scholar
Li, Q., Sone, S., & Doi, K., 2003, Selective enhancement filters for nodules, vessels, and airway walls in twoand three-dimensional CT scans. Medical Physics 30, 2040Google Scholar
Linsen, L., Long, T., Rosenthal, P., & Rosswog, S., 2008, Surface extraction from multi-field particle volume data using multi-dimensional cluster visualization. IEEE Transactions on Visualization and Computer Graphics 1, (6), 14831490Google Scholar
Lorensen, W., & Cline, H., 1987, Marching cubes: A high resolution 3, surface construction algorithm. In: Proceedings of the 14th annual confe rence on Computer graphics and interactive techniques. ACM, p. 169Google Scholar
Magnor, M., Hildebrand, K., Lintu, A., & Hanson, A., 2005, Reection nebula visualization. IEEE Visualization, 2005, VIS 05, 255262Google Scholar
Magnor, M., Kindlmann, G., Duric, N., & Hansen, C., 2004, Constrained inverse volume rendering for planetary nebulae. In: IEEE Visualization, 2004, pp. 8390Google Scholar
McAllister, D., 2006, Display Technology: Stereo & 3, Display Technologies. Encyclopaedia on Imaging Science and Technology, 13271344Google Scholar
McCormick, B., DeFanti, T., & Brown, M., 1987, Visualization in Scientific Computing. Computer Graphics 2, (6)Google Scholar
McMullin, J., Golap, K., & Myers, S., 2004, The AIPS ++ Project. In: Astronomical Data Analysis Software and Systems (ADASS) XIII. Vol. 314, p. 468Google Scholar
Mickus, K., Brugel, E., Domik, G., & Ayres, T., 1990a, A Case Study: Multi-Sensor Data Analysis of HH Objects Via STAR: A Scientific Toolkit for Astrophysical Research. In: Bulletin of the American Astronomical Society. Vol. 22, p. 1259Google Scholar
Mickus, K., Domik, G., Brugel, E., & Ayres, T., 1990b, STAR-A Scientific Toolkit for Astrophysical Research. In: Bulletin of the American Astronomical Society. Vol. 22, p. 828Google Scholar
Miller, J., Quammen, C., & Fleenor, M., 2006, Interactive visualization of intercluster galaxy structures in the horologium-reticulum supercluster. IEEE Transactions on Visualization and Computer Graphics 1, (5), 11491156Google Scholar
Montani, C., Scateni, R., & Scopigno, R., 1994, A modi fied look-up table for implicit disambiguation of marching cubes. The Visual Computer 1, (6), 353355Google Scholar
Murphy, T., Lamb, P., Owen, C., & Marquarding, M., 2006, Data Storage, Processing, and Visualization for the Australia Telescope Compact Array. Publications of the Astronomical Society of Australia 23, 2532Google Scholar
Nadeau, D., 2000, Volume scene graphs. In: Proceedings of the 200, IEEE symposium on Volume visualization. ACM, pp. 4956Google Scholar
Nadeau, D., Genetti, J., Napear, S., Pailthorpe, B., Emmart, C., Wesselak, E., & Davidson, D., 2001, Visualizing stars and emission nebulae. In: Computer Graphics Forum. Vol. 20, pp. 2733Google Scholar
Nakasone, A., Prendinger, H., Holland, S., Miura, K., Hut, P., & Makino, J., 2009, AstroSim: collaborative visualization of an astrophysics simulation in second life. IEEE Computer Graphics and Applications 2, (5), 6981Google Scholar
Navratil, P., Johnson, J., & Bromm, V., 2007, Visualization of cosmological particle-based datasets. IEEE transactions on visualization and computer graphics 1, (6), 17121718Google Scholar
Norman, M., Shalf, J., Levy, S., & Daues, G., 1999, Diving deep: data-management and visualization strategies foradaptive mesh refinement simulations. Computing in Science & Engineering 1, (4), 3647Google Scholar
Norris, R., 1994, The Challenge of Astronomical Visualisation. In: Astronomical Data Analysis Software and Systems III. Vol. 61, p. 51Google Scholar
Oosterloo, T., 1995, Visualisation of Radio Data. In: Astronomical socity of Australia Proceedings. Vol. 12, p. 215Google Scholar
Oosterloo, T., 1996, Adaptive filtering and masking of HI data cubes. Vistas in Astronomy 4, (4), 571577Google Scholar
Ostriker, J., & Norman, M., 1997, Cosmology of the early universe viewed through the new infrastructure. Communications of the ACM 4, (11), 94Google Scholar
Palomino, H., 2003, Visualization of 3, numerical simulations in astrophysics using the Vr-cube. Master's thesis, Department of Numerical Analysis and Computer Science, Royal Institute of Technology, Stockholm, SwedenGoogle Scholar
Pérez, M., 1997, Alternative Astronomical Software Packages. Astrophysics and Space Science 25, (1), 271284Google Scholar
Pesenson, M., Pesenson, I., & McCollum, B., 2010, The Data Big Bang and the Expanding Digital Universe: High-Dimensional, Complex and Massive Data Sets in an Inationary Epoch. Advances in Astronomy 2010, 58Google Scholar
Plante, R., Rajlich, P., Pietrowitz, S., Xie, W., & Qamar, A., 1999, Converging Horizons: Collaborative 2/3, Visualization Tools for Astronomy. In: Astronomical Society of the Pacific Conference Series. Vol. 172, Astronomical Society of the Pacific, pp. 433436Google Scholar
Plewa, T., Linde, T., & Weirs, V. G. (Eds.) (2005). Adaptive Mesh Refinement – Theory and Applications. Springer, BerlinGoogle Scholar
Quinn, P. J., Barnes, D. G., Csabai, I., Cui, C., Genova, F., Hanisch, B., Kembhavi, A., Kim, S. C., Lawrence, A., Malkov, O., Ohishi, M., Pasian, F., Schade, D., & Voges, W., 2004, The International Virtual Observatory Alliance: recent technical developments and the road ahead. In: Quinn, P. J. & Bridger, A. (Eds.), Society of Photo-Optical Instrumentation Engineers (SPIE) Conference Series. Vol. 549, of Society of Photo-Optical Instrumentation Engineers (SPIE) Conference Series. pp. 137145Google Scholar
Rector, T., Levay, Z., Frattare, L., English, J., & Puuohau-Pummill, K., 2005, Philosophy for the Creation of Astronomical Images. In: In IAU Commission 55, Communic ating Astronomy with the Public 2005, pp. 194204Google Scholar
Rector, T., Levay, Z., Frattare, L., English, J., & Puuohau-Pummill, K., 2007, Image-Processing Techniques for the Creation of Presentation-Quality Astronomical Images. The Astronomical Journal 133, 598611Google Scholar
Rots, A., 1986, Data display: searching for new avenues in image analysis. In: Synthesis Imaging. pp. 231252Google Scholar
Röttgering, H., 2003, LOFAR, a new low frequency radio telescope. New Astronomy Review 47, 405409Google Scholar
Sanchez, S., 2004, E3D, the Euro3, visualization tool I: Description of the program and its capabilities. Astronomisc he Nachrichten 32, (2)Google Scholar
Sanchez, S., Becker, T., & Kelz, A., 2004, E3D, the Euro3, visualization tool II: Mosaics, VIMOS data and large IFUs of the future. Astronomische Nachrichten 32, (2)Google Scholar
Sato, Y., Nakajima, S., Shiraga, N., Atsumi, H., Yoshida, S., Koller, T., Gerig, G., & Kikinis, R., 1998, Three-dimensional multi-scale line filter for segmentation and visualization of curvilinear structures in medical images. Medical Image Analysis 2, (2), 143168Google Scholar
Sato, Y., Westin, C., Bhalerao, A., Nakajima, S., Shiraga, N., Tamura, S., & Kikinis, R., 2000, Tissue classi fication based on 3, local intensity struct ures for volume rendering. IEEE Transactions on Visualization and Computer Graphics 6, (2)Google Scholar
Schroeder, W., Martin, K., & Lorensen, B., 2006, An Object-Oriented Approach To 3, Graphics. KitwareGoogle Scholar
Shneiderman, B., November 1994, Dynamic queries for visual information seeking. IEEE Software 11, 7077Google Scholar
Spence, R., 2001, Information visualization. Addison-Wesley, Reading, MAGoogle Scholar
Springel, V., 2005, The cosmological simulation code GADGET-2, Mon. Not. R. Astron. Soc 364, 11051134Google Scholar
Springel, V., 2010, E pur si muove: Galilean-invariant cosmological hydrodynamical simulations on a moving mesh. MNRAS 401, 791851Google Scholar
Springel, V., White, S., Jenkins, A., Frenk, C., Yoshida, N., Gao, L., Navarro, J., Thacker, R., Croton, D., Helly, J., et al. , 2005, Simulations of the formation, evolution and clustering of galaxies and quasars. Nature 43, (7042), 629636Google Scholar
Staff, J., Jorgensen, M., & Ouyed, R., 2004, JETGETAn analysis and visualization tool for (magneto-) hydrodynamic jet simulations. Arxiv preprint astroph/0402121Google Scholar
Szalay, A., & Gray, J., 2001, The world-wide telescope. Science 29, (5537), 2037Google Scholar
Szalay, A., & Gray, J., 2006, 202, Computing: Science in an exponential world. Nature 44, (7083), 413414Google Scholar
Szalay, T., Springel, V., & Lemson, G., Nov. 2008, GPUBased Interactive Visualization of Billion Point Cosmological Simulations. ArXiv e-printsGoogle Scholar
Taylor, J., Boch, T., Comparato, M., Taylor, M., & Winstanley, N., 2006, PLASTIC – a protocol for desktop application inter-operability. IVOA Note http://ivoa.net/Documents/latest/PlasticDesktopInterop.htmlGoogle Scholar
Teuben, P., Hut, P., Levy, S., Makino, J., McMillan, S., Zwart, S., Shara, M., & Emmart, C., 2001, Immersive 4-d interactive visualization of large-scale simulation. volume 238, Astronomical Society of the Pacific, 499Google Scholar
Van Buren, D., Curtis, P., Nichols, D., & Brundage, M., 1995, The AstroVR Collaboratory, An Online Multi-User Environment for Research in Astrophysics. In: Astronomical Data Analysis Software and Systems IV, ASP Conference Series: Astronomical Society of the Pacific. Vol. 77, p. 99Google Scholar
Wang, L., & Mueller, K., 2008, Harmonic colormaps for volume visualization. In: IEEE/EG Symposium on Volume and Point-Based Graphics, 2008Google Scholar
Weiner, B., Blanton, M., Coil, A., Cooper, M., Davé, R., Hogg, D., Holden, B., Jonsson, P., Kassin, S., Lotz, J., et al. , 2009, Astronomical Software Wants To Be Free: A Manifesto. Arxiv preprint arXiv:0903.3971Google Scholar
Welling, J., & Derthick, M., 2000, Visualization of large multi-dimensional datasets. Arxiv preprint astroph/0008186Google Scholar
Williams, R., & De Young, D., 2009, The Role of the Virtual Observatory in the Next Decade. In: astro2010, The Astronomy and Astrophysics Decadal Survey. Vol. 201, of ArXiv Astrophysics e-printsGoogle Scholar
Wood, Z., Schroder, P., Breen, D., & Desbrun, M., 2000, Semi-regular mesh extraction from volumes. In: Proceedings of the conference on Visualization' 00, IEEE Computer Society Press, pp. 275282Google Scholar