The DNA of information design for charts and diagrams

Richards, Clive; Engelhardt, Yuri

doi:10.1075/idj.25.3.05ric

Article published In: Information Design Journal
Vol. 25:3 (2019) ► pp.278–293

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The DNA of information design for charts and diagrams

Clive Richards

Yuri Engelhardt

Published online: 22 October 2020

https://doi.org/10.1075/idj.25.3.05ric

Abstract

A comprehensive framework is presented for analyzing and specifying an extensive range of visualizations, such as statistical charts, maps, family trees, Venn diagrams, flow charts, texts using indenting, technical drawings and scientific illustrations. This paper describes how the fundamental ‘DNA’ building blocks of visual encoding and composition can be combined into ‘visualization patterns’ that specify these and other types of visualizations. We offer different ways of specifying each visualization pattern, including through a DNA tree diagram and through a rigorously systematic natural language sentence. Using this framework, a design tool is proposed for exploring visualization design options.

Keywords: visual encoding, graphic language, visual grammar, visualization patterns, chart types, design space, diagrammatic DNA

Article outline

1.Introduction
2.Methodology
3.The DNA framework of visualization
4.Specification with tree diagrams and with natural language
5.Types of information that can be represented visually
6.Visual encodings
7.Directions and layout principles
8.Visual components
9.Modes of visual encoding, depiction, and correspondence
10.Mode of correspondence
11.Mode of depiction
12.Reference elements
13.Visual treatment
14.Using the DNA framework as a design tool
15.Discussion and conclusions
Acknowledgements
Notes
References

References (25)

References

Ashwin, C. (1979). The ingredients of style in contemporary illustration: A case study. Information Design Journal, 1(1), 51–67.

Bertin, J. (1967/1983). Semiology of graphics: Diagrams, networks, maps. University of Wisconsin Press. [original: Sémiologie graphique. Paris: Gauthier-Villars.]

(1977/1981). Graphics and graphic information processing. Berlin: Walter de Gruyter & Co. [original: Le graphique et le traitement graphique de l’information. Paris: Flammarion.]

Card, S. K. & Mackinlay, J. (1997). The structure of the information visualization design space. In Proceedings of the 1997 IEEE Symposium on Information Visualization (InfoVis ’97) (pp. 92–99). Washington, DC: IEEE Computer Society.

Card, S. K., Mackinlay, J., & Shneiderman, B. (1999). Readings in information visualization: Using vision to think. San Francisco: Morgan Stanley Kaufmann.

Engelhardt, Y. (2002). The language of graphics. PhD thesis, University of Amsterdam.

Engelhardt, Y. & Richards, C. (2018). A framework for analyzing and designing diagrams and graphics. In P. Chapman, G. Stapleton, A. Moktefi, S. Perez-Kriz, & F. Bellucci (Eds.), Diagrams 2018: Diagrammatic representation and inference (pp. 201–209). Cham, Switzerland: Springer.

(2020). The DNA framework of visualization. In A. Pietarinen, P. Chapman, L. Bosveld de Smet, V. Giardino, J. Corter, & S. Linker (Eds.), Diagrams 2020: Diagrammatic representation and inference. Cham, Switzerland: Springer.

Gombrich, E. H. (1977). Art and illusion (5th ed.). Oxford: Phaidon.

Heer, J., Bostock, M., & Ogievetsky, V. (2010). A tour through the visualization zoo. ACM Queue, 8(5), 1–22.

Holmes, N. (1984). Designer’s guide to creating charts & diagrams. New York: Watson-Guptill.

Horn, R. E. (1998). Visual language: Global communication for the 21st century. Bainbridge Island, WA: MacroVU, Inc.

Hutchins, M. P. & Adler, M. J. (1932). Diagrammatics. New York: Random House.

Johnson, M. (1987). The body in the mind. University of Chicago Press.

Lakoff, G. (1987). Women, fire, and dangerous things. The University of Chicago Press.

McCloud, S. (1993). Understanding comics: The invisible art. Princeton: Kitchen Sink Press.

Munzer, T. (2014). Visualization analysis and design. Boca Ratan, USA: CRC Press.

Richards, C. (1984). Diagrammatics. PhD thesis, Royal College of Art, London.

(2000). Getting the picture: Diagram design and the information revolution. Information Design Journal, 9(2/3), 87–110.

Richards, C. & Engelhardt, Y. (forthcoming). Diagrammatics: The DNA of visualization. In C. Richards (Ed.), Elements of diagramming: Theoretical frameworks, design methods, domains of practice. London: Routledge.

Tversky, B. (1995). Cognitive origins of graphic productions. In F. T. Marchese (Ed.), Understanding images (pp. 29–53). New York: Springer.

Twyman, M. (1979). A schema for the study of graphic language. In P. A. Kolers, M. E. Wrolstad, & H. Bouma (Eds.), Processing of visible language, v. 11 (pp. 117–150). New York: Plenum Press.

Ware, C. (2008). Visual thinking for design. San Francisco: Morgan Kaufmann Publishers.

Wilkinson, L. (2005). The grammar of graphics (2nd ed.). New York: Springer.

Wills, G. (2012). Visualizing time. New York: Springer.

Cited by (2)

Cited by two other publications

Engelhardt, Yuri & Clive Richards

2021. A Universal Grammar for Specifying Visualization Types. In Diagrammatic Representation and Inference [Lecture Notes in Computer Science, 12909], ► pp. 395 ff.

[no author supplied]

2023. Beck at 90. The Cartographic Journal 60:4 ► pp. 264 ff.

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