To advance research and improve the scientific return on data collection and interpretation efforts in the geosciences, we have developed methods of interactive visualization, with a special focus on immersive virtual reality (VR) environments. Earth sciences employ a strongly visual approach to the measurement and analysis of geologic data due to the spatial and temporal scales over which such data ranges. As observations and simulations increase in size and complexity, the Earth sciences are challenged to manage and interpret increasing amounts of data. Reaping the full intellectual benefits of immersive VR requires us to tailor exploratory approaches to scientific problems. These applications build on the visualization method's strengths, using both 3D perception and interaction with data and models, to take advantage of the skills and training of the geological scientists exploring their data in the VR environment. This interactive approach has enabled us to develop a suite of tools that are adaptable to a range of problems in the geosciences and beyond.
Описание
Enabling scientific workflows in virtual reality | Proceedings of the 2006 ACM international conference on Virtual reality continuum and its applications
%0 Conference Paper
%1 kreylos2006enabling
%A Kreylos, Oliver
%A Bawden, Gerald
%A Bernardin, Tony
%A Billen, Magali I.
%A Cowgill, Eric S.
%A Gold, Ryan D.
%A Hamann, Bernd
%A Jadamec, Margarete
%A Kellogg, Louise H.
%A Staadt, Oliver G.
%A Sumner, Dawn Y.
%B Proceedings of the 2006 ACM international conference on Virtual reality continuum and its applications
%C New York, NY, USA
%D 2006
%I Association for Computing Machinery
%K immersive visualization
%P 155–162
%R 10.1145/1128923.1128948
%T Enabling scientific workflows in virtual reality
%U https://doi.org/10.1145/1128923.1128948
%X To advance research and improve the scientific return on data collection and interpretation efforts in the geosciences, we have developed methods of interactive visualization, with a special focus on immersive virtual reality (VR) environments. Earth sciences employ a strongly visual approach to the measurement and analysis of geologic data due to the spatial and temporal scales over which such data ranges. As observations and simulations increase in size and complexity, the Earth sciences are challenged to manage and interpret increasing amounts of data. Reaping the full intellectual benefits of immersive VR requires us to tailor exploratory approaches to scientific problems. These applications build on the visualization method's strengths, using both 3D perception and interaction with data and models, to take advantage of the skills and training of the geological scientists exploring their data in the VR environment. This interactive approach has enabled us to develop a suite of tools that are adaptable to a range of problems in the geosciences and beyond.
%@ 1595933247
@inproceedings{kreylos2006enabling,
abstract = {To advance research and improve the scientific return on data collection and interpretation efforts in the geosciences, we have developed methods of interactive visualization, with a special focus on immersive virtual reality (VR) environments. Earth sciences employ a strongly visual approach to the measurement and analysis of geologic data due to the spatial and temporal scales over which such data ranges. As observations and simulations increase in size and complexity, the Earth sciences are challenged to manage and interpret increasing amounts of data. Reaping the full intellectual benefits of immersive VR requires us to tailor exploratory approaches to scientific problems. These applications build on the visualization method's strengths, using both 3D perception and interaction with data and models, to take advantage of the skills and training of the geological scientists exploring their data in the VR environment. This interactive approach has enabled us to develop a suite of tools that are adaptable to a range of problems in the geosciences and beyond.},
added-at = {2024-04-15T13:58:56.000+0200},
address = {New York, NY, USA},
author = {Kreylos, Oliver and Bawden, Gerald and Bernardin, Tony and Billen, Magali I. and Cowgill, Eric S. and Gold, Ryan D. and Hamann, Bernd and Jadamec, Margarete and Kellogg, Louise H. and Staadt, Oliver G. and Sumner, Dawn Y.},
biburl = {https://www.bibsonomy.org/bibtex/226b066a6b4ebd6143d2a2db31bbcb304/abernstetter},
booktitle = {Proceedings of the 2006 ACM international conference on Virtual reality continuum and its applications},
day = 14,
description = {Enabling scientific workflows in virtual reality | Proceedings of the 2006 ACM international conference on Virtual reality continuum and its applications},
doi = {10.1145/1128923.1128948},
interhash = {b9de784d1e84e6e4372c30d3ce31caf2},
intrahash = {26b066a6b4ebd6143d2a2db31bbcb304},
isbn = {1595933247},
keywords = {immersive visualization},
location = {Hong Kong, China},
month = {6},
pages = {155–162},
publisher = {Association for Computing Machinery},
series = {VRCIA '06},
timestamp = {2024-04-15T13:58:56.000+0200},
title = {Enabling scientific workflows in virtual reality},
url = {https://doi.org/10.1145/1128923.1128948},
year = 2006
}