Abstract
The current ubiquity of data collection is providing unprecedented opportunities for knowledge discovery and extraction. Data sources can be large, complex, heterogeneous, structured, and unstructured. In order to explore such data and exploit opportunities within the data deluge, tools and techniques are being developed to help data users generate hypotheses, explore data trends and ultimately develop insights and formulate narratives with their data. These tools often rely on visual representations of the data coupled with interactive computer interfaces to aid the exploration and analysis process. Such representations fall under the purview of visualization, in which scientists have worked on systematically exploiting the human visual system as a key part of data analysis. Research in this area has been inspired by a number of historical sources, examples include physicist James Maxwell’s sculpture of a thermodynamic surface in 1874, Leonardo da Vinci’s hand-drawn illustration of water from his studies to determine the processes underlying water flow, or the flow map of Napoleon’s March on Moscow produced by Charles Minard in 1869. Each of these examples attempts to explain data in a visual manner, and, as visualization has progressed, principles and practices have been adopted to standardize representations, and, more importantly, better exploit properties of the human visual system.
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References
Aigner W, Miksch S, Muller W, Schumann H, Tominski C (2008) Visual methods for analyzing time-oriented data. IEEE Trans Vis Comput Graph 14(1):47–60
Andrienko N, Andrienko G (2006) Exploratory analysis of spatial and temporal data: a systematic approach. Springer, Berlin
Ankerst M, Berchtold B, Keim DA (1998) Similarity clustering of dimensions for an enhanced visualization of multidimensional data. In: IEEE symposium on information visualization, Phoenix, pp 52–62
Anselin L (1998) Exploratory spatial data analysis in a geocomputational environment. In: Longley PA, Brooks SM, McDonnell R, MacMillan B (eds) Geocomputation: a primer. Wiley, Chichester, pp 77–94
Anselin L, Syabri I, Kho Y (2006) GeoDa: an introduction to spatial data analysis. Geogr Anal 38(1):5–22
Bertin J (1967) The semiology of graphics. ESRI Press, Redlands
Cleveland WS (1985) The elements of graphing data. Wadsworth, Monterey
Cleveland WS (1993) Visualizing data. Hobart Press, Summit
Few S (2009) Now you see it: simple visualization techniques for quantitative analysis. Analytics Press, Oakland
Fischer MM, Getis A (eds) (2010) Handbook of applied spatial analysis. Software tools, methods and applications. Springer, Berlin/Heidelberg/New York
Furnas G (1986) Generalized fisheye views. In: Proceedings of ACM CHI, Boston, pp 16–23
Gutwin C, Skopik A (2003) Fisheyes are good for large steering tasks. In: Proceedings of the SIGCHI conference on human factors in computing systems, Ft. Lauderdale, pp 201–208
Hägerstrand T (1970) What about people in regional science? Pap Reg Sci 24(1):6–21
Hardin C, Maffi L (1997) Color categories in thought and language. Cambridge University Press, Cambridge
Harrower MA, Brewer CA (2003) ColorBrewer.org: an online tool for selecting color schemes for maps. Cartogr J 40(1):27–37
Inselberg A (1985) The plane with parallel coordinates. Vis Comput 1(4):69–91
Jul S, Furnas GW (1998) Critical zones in desert fog: aids to multiscale navigation. In: Proceedings of the 11th annual ACM symposium on user interface software and technology, San Francisco, pp 97–106
MacEachren AM (1994) Visualization in modern cartography: setting the agenda. In: MacEachren AM, Taylor DRF (eds) Visualization in modern cartography. Pergamon, Oxford, pp 1–12
MacEachren AM (1995) How maps work. Guilford, New York
Monmonier MS (1972) Contiguity-biased class-interval selection: a method for simplifying patterns on statistical maps. Geogr Rev 62(2):203–228
Monmonier M (1989) Geographic brushing: enhancing exploratory analysis of the scatterplot matrix. Geogr Anal 21(1):81–84
North C, Shneiderman B (2000) Snap-together visualization: evaluating coordination usage and construction. Int J Hum Comput Stud 51:715–739
Pearson K (1895) Contributions to the mathematical theory of evolution. II. Skew variation in homogenous material. Philos Trans R Soc A Math Phys Eng Sci 186:326–343
Shneiderman B (1996) The eyes have it: a task by data type taxonomy for information visualizations. In: Proceedings of the IEEE symposium on visual languages, Las Alamos, pp 336–343
Sturges HA (1926) The choice of a class interval. J Am Stat Assoc 21(153):65–66
Tufte ER (1983) The visual display of quantitative information. Graphics Press, Cheshire
Tukey JW (1977) Exploratory data analysis. Addison-Wesley, Reading
Wilkinson L (2005) The grammar of graphics. Springer, New York
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Maciejewski, R. (2018). Geovisualization. In: Fischer, M., Nijkamp, P. (eds) Handbook of Regional Science. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-36203-3_70-1
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DOI: https://doi.org/10.1007/978-3-642-36203-3_70-1
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