Data visualization relies on efficient rendering to allow users to interactively explore and understand their data. However, achieving interactive frame rates is often challenging, especially for high-resolution displays or large datasets. In computer graphics, several methods temporally reconstruct full-resolution images from multiple consecutive lower-resolution frames. Besides providing temporal image stability, they amortize the rendering costs over multiple frames and thus improve the minimum frame rate. We present a method that adopts this idea to accelerate 2D information visualization, without requiring any changes to the rendering itself. By exploiting properties of orthographic projection, our method significantly improves rendering performance while minimizing the loss of image quality during camera manipulation. For static scenes, it quickly converges to the full-resolution image. We discuss the characteristics and different modes of our method concerning rendering performance and image quality and the corresponding trade-offs. To improve ease of use, we provide automatic resolution scaling in our method to adapt to user-defined target frame rate. Finally, we present extensive rendering benchmarks to examine real-world performance for examples of parallel coordinates and scatterplot matrix visualizations, and discuss appropriate application scenarios and contraindications for usage.
%0 Journal Article
%1 Becher2023
%A Becher, Michael
%A Heinemann, Moritz
%A Marmann, Thomas
%A Reina, Guido
%A Weiskopf, Daniel
%A Ertl, Thomas
%D 2023
%J Journal of Visualization
%K myown vis(us) visus:reina
%R 10.1007/s12650-023-00925-3
%T Accelerated 2D visualization using adaptive resolution scaling and temporal reconstruction
%U https://doi.org/10.1007/s12650-023-00925-3
%X Data visualization relies on efficient rendering to allow users to interactively explore and understand their data. However, achieving interactive frame rates is often challenging, especially for high-resolution displays or large datasets. In computer graphics, several methods temporally reconstruct full-resolution images from multiple consecutive lower-resolution frames. Besides providing temporal image stability, they amortize the rendering costs over multiple frames and thus improve the minimum frame rate. We present a method that adopts this idea to accelerate 2D information visualization, without requiring any changes to the rendering itself. By exploiting properties of orthographic projection, our method significantly improves rendering performance while minimizing the loss of image quality during camera manipulation. For static scenes, it quickly converges to the full-resolution image. We discuss the characteristics and different modes of our method concerning rendering performance and image quality and the corresponding trade-offs. To improve ease of use, we provide automatic resolution scaling in our method to adapt to user-defined target frame rate. Finally, we present extensive rendering benchmarks to examine real-world performance for examples of parallel coordinates and scatterplot matrix visualizations, and discuss appropriate application scenarios and contraindications for usage.
@article{Becher2023,
abstract = {Data visualization relies on efficient rendering to allow users to interactively explore and understand their data. However, achieving interactive frame rates is often challenging, especially for high-resolution displays or large datasets. In computer graphics, several methods temporally reconstruct full-resolution images from multiple consecutive lower-resolution frames. Besides providing temporal image stability, they amortize the rendering costs over multiple frames and thus improve the minimum frame rate. We present a method that adopts this idea to accelerate 2D information visualization, without requiring any changes to the rendering itself. By exploiting properties of orthographic projection, our method significantly improves rendering performance while minimizing the loss of image quality during camera manipulation. For static scenes, it quickly converges to the full-resolution image. We discuss the characteristics and different modes of our method concerning rendering performance and image quality and the corresponding trade-offs. To improve ease of use, we provide automatic resolution scaling in our method to adapt to user-defined target frame rate. Finally, we present extensive rendering benchmarks to examine real-world performance for examples of parallel coordinates and scatterplot matrix visualizations, and discuss appropriate application scenarios and contraindications for usage.},
added-at = {2023-07-11T12:52:20.000+0200},
author = {Becher, Michael and Heinemann, Moritz and Marmann, Thomas and Reina, Guido and Weiskopf, Daniel and Ertl, Thomas},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/25708cb0d6be56f9ac100aa9c1992fb7e/guidoreina},
day = 08,
doi = {10.1007/s12650-023-00925-3},
interhash = {03146d71b11aedc35b5c00a55cbb6518},
intrahash = {5708cb0d6be56f9ac100aa9c1992fb7e},
issn = {1875-8975},
journal = {Journal of Visualization},
keywords = {myown vis(us) visus:reina},
month = jul,
timestamp = {2023-07-11T12:52:20.000+0200},
title = {Accelerated 2D visualization using adaptive resolution scaling and temporal reconstruction},
url = {https://doi.org/10.1007/s12650-023-00925-3},
year = 2023
}