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Wikipedia

Cartogram

January 13, 2023

For broader coverage of this topic, see Thematic map.
Not to be confused with Cartography.

A cartogram (also called a value-area map or an anamorphic map, the latter common among German-speakers) is a thematic map of a set of features (countries, provinces, etc.), in which their geographic size is altered to be directly proportional to a selected ratio-level variable, such as travel time, population, or GNP. Geographic space itself is thus warped, sometimes extremely, in order to visualize the distribution of the variable. It is one of the most abstract types of map; in fact, some forms may more properly be called diagrams. They are primarily used to display emphasis and for analysis as nomographs.[1]

Mosaic cartogram showing the distribution of the global population. Each of the 15,266 pixels represents the home country of 500,000 people – cartogram by Max Roser for Our World in Data

Cartograms leverage the fact that size is the most intuitive visual variable for representing a total amount.[2] In this, it is a strategy that is similar to proportional symbol maps, which scale point features, and many flow maps, which scale the weight of linear features. However, these two techniques only scale the map symbol, not space itself; a map that stretches the length of linear features is considered a linear cartogram (although additional flow map techniques may be added). Once constructed, cartograms are often used as a base for other thematic mapping techniques to visualize additional variables, such as choropleth mapping.

History

 
One of Levasseur's 1876 cartograms of Europe, the earliest known published example of this technique.

The cartogram was developed later than other types of thematic maps, but followed the same tradition of innovation in France.[3] The earliest known cartogram was published in 1876 by French statistician and geographer Pierre Émile Levasseur, who created a series of maps that represented the countries of Europe as squares, sized according to a variable and arranged in their general geographical position (with separate maps scaled by area, population, religious adherents, and national budget).[4] Later reviewers have called his figures a statistical diagram rather than a map, but Levasseur referred to it as a carte figurative, the common term then in use for any thematic map. He produced them as teaching aids, immediately recognizing the intuitive power of size as a visual variable: "It is impossible that the child is not struck by the importance of the trade of Western Europe in relation to that of Eastern Europe, that he does not notice how much England, which has a small territory but outweighs other nations by its wealth and especially by its navy, how much on the contrary Russia which, by its area and its population occupies the first rank, is still left behind by other nations in the commerce and navigation."

Levasseur's technique does not appear to have been adopted by others, and relatively few similar maps appear for many years. The next notable development was a pair of maps by Hermann Haack and Hugo Weichel of the 1898 election results for the German Reichstag in preparation for the 1903 election, the earliest known contiguous cartogram.[5] Both maps showed a similar outline of the German Empire, with one subdivided into constituencies to scale, and the other distorting the constituencies by area. The subsequent expansion of densely populated areas around Berlin, Hamburg, and Saxony was intended to visualize the controversial tendency of the mainly urban Social Democrats to win the popular vote, while the mainly rural Zentrum won more seats (thus presaging the modern popularity of cartograms for showing the same tendencies in recent elections in the United States).[6]

The continuous cartogram emerged soon after in the United States, where a variety appeared in the popular media after 1911.[7][8] Most were rather crudely drawn compared to Haack and Weichel, with the exception of the "rectangular statistical cartograms" by the American master cartographer Erwin Raisz, who claimed to have invented the technique.[9][10]

When Haack and Weichel referred to their map as a kartogramm, this term was commonly being used to refer to all thematic maps, especially in Europe.[11][12] It was not until Raisz and other academic cartographers stated their preference for a restricted use of the term in their textbooks (Raisz initially espousing value-area cartogram) that the current meaning was gradually adopted.[13][14]

The primary challenge of cartograms has always been the drafting of the distorted shapes, making them a prime target for computer automation. Waldo R. Tobler developed one of the first algorithms in 1963, based on a strategy of warping space itself rather than the distinct districts.[15] Since then, a wide variety of algorithms have been developed (see below), although it is still common to craft cartograms manually.[1]

General principles

Since the early days of the academic study of cartograms, they have been compared to map projections in many ways, in that both methods transform (and thus distort) space itself.[15] The goal of designing a cartogram or a map projection is therefore to represent one or more aspects of geographic phenomena as accurately as possible, while minimizing the collateral damage of distortion in other aspects. In the case of cartograms, by scaling features to have a size proportional to a variable other than their actual size, the danger is that the features will be distorted to the degree that they are no longer recognizable to map readers, making them less useful.

As with map projections, the tradeoffs inherent in cartograms have led to a wide variety of strategies, including manual methods and dozens of computer algorithms that produce very different results from the same source data. The quality of each type of cartogram is typically judged on how accurately it scales each feature, as well as on how (and how well) it attempts to preserve some form of recognizability in the features, usually in two aspects: shape and topological relationship (i.e., retained adjacency of neighboring features).[16][17] It is likely impossible to preserve both of these, so some cartogram methods attempt to preserve one at the expense of the other, some attempt a compromise solution of balancing the distortion of both, and other methods do not attempt to preserve either one, sacrificing all recognizability to achieve another goal.

Area cartograms

 
Cartogram of Germany, with the states and districts resized according to population

The area cartogram is by far the most common form; it scales a set of region features, usually administrative districts such as counties or countries, such that the area of each district is directly proportional to a given variable. Usually this variable represents the total count or amount of something, such as total Population, Gross domestic product, or the number of retail outlets of a given brand or type. Other strictly positive ratio variables can also be used, such as GDP per capita or Birth rate, but these can sometimes produce misleading results because of the natural tendency to interpret size as total amount.[2] Of these, total population is probably the most common variable, sometimes called an isodemographic map.

The various strategies and algorithms have been classified a number of ways, generally according to their strategies with respect to preserving shape and topology. Those that preserve shape are sometimes called equiform, although isomorphic (same-shape) or homomorphic (similar-shape) may be better terms. Three broad categories are widely accepted: contiguous (preserve topology, distort shape), non-contiguous (preserve shape, distort topology), and diagrammatic (distort both). Recently, more thorough taxonomies by Nusrat and Kobourov, Markowska, and others have built on this basic framework in an attempt to capture the variety in approaches that have been proposed and in the appearances of the results.[18][19] The various taxonomies tend to agree on the following general types of area cartograms.

Anamorphic Projection

See also: Anamorphosis

This is a type of contiguous cartogram that uses a single parametric mathematical formula (such as a polynomial curved surface) to distort space itself to equalize the spatial distribution of the chosen variable, rather than distorting the individual features. Because of this distinction, some have preferred to call the result a pseudo-cartogram.[20] Tobler's first computer cartogram algorithm was based on this strategy,[15][21] for which he developed the general mathematical construct on which his and subsequent algorithms are based.[15] This approach first models the distribution of the chosen variable as a continuous density function (usually using a least squares fitting), then uses the inverse of that function to adjust the space such that the density is equalized. The Gastner-Newman algorithm, one of the most popular tools used today, is a more advanced version of this approach.[22][23] Because they do not directly scale the districts, there is no guarantee that the area of each district is exactly equal to its value.

Shape-warping contiguous cartograms

 
Contiguous cartogram (Gastner-Newman) of the world with each country rescaled in proportion to the hectares of certified organic farming[24]

Also called irregular cartograms or deformation cartograms,[19] This is a family of very different algorithms that scale and deform the shape of each district while maintaining adjacent edges. This approach has its roots in the early 20th Century cartograms of Haack and Weichel and others, although these were rarely as mathematically precise as current computerized versions. The variety of approaches that have been proposed include cellular automata, quadtree partitions, cartographic generalization, medial axes, spring-like forces, and simulations of inflation and deflation.[18] Some attempt to preserve some semblance of the original shape (and may thus be termed homomorphic),[25] but these are often more complex and slower algorithms than those that severely distort shape.

Non-contiguous isomorphic cartograms

 
Non-contiguous isomorphic cartogram of the Czech Republic, in which the size of each district is proportional to the Catholic percentage and the color (choropleth) representing the proportion voting for the KDU-CSL party in 2010, showing a strong correlation.

This is perhaps the simplest method for constructing a cartogram, in which each district is simply reduced or enlarged in size according to the variable without altering its shape at all.[16] In most cases, a second step adjusts the location of each shape to reduce gaps and overlaps between the shapes, but their boundaries are not actually adjacent. While the preservation of shape is a prime advantage of this approach, the results often have a haphazard appearance because the individual districts do not fit together well.

Diagrammatic (Dorling) cartograms

 
Diagrammatic (Dorling) cartogram of the number of times each country is linked in the French-language Wikipedia.

In this approach, each district is replaced with a simple geometric shape of proportional size. Thus, the original shape is completely eliminated, and contiguity may be retained in a limited form or not at all. Although they are usually referred to as Dorling cartograms after Daniel Dorling's 1996 algorithm first facilitated their construction,[26] these are actually the original form of cartogram, dating back to Levasseur (1876)[4] and Raisz (1934).[9] Several options are available for the geometric shapes:

  • Circles (Dorling), typically brought together to be touching and arranged to retain some semblance of the overall shape of the original space.[26] These often look like proportional symbol maps, and some consider them to be a hybrid between the two types of thematic map.
  • Squares (Levasseur/Demers), treated in much the same way as the circles, although they do not generally fit together as simply.
  • Rectangles (Raisz), in which the height and width of each rectangular district is adjusted to fit within an overall shape. The result looks much like a treemap diagram, although the latter is generally sorted by size rather than geography. These are often contiguous, although the contiguity may be illusory because many of the districts that are adjacent in the map may not be the same as those that are adjacent in reality.

Because the districts are not at all recognizable, this approach is most useful and popular for situations in which the shapes would not be familiar to map readers anyway (e.g., U.K. parliamentary constituencies) or where the districts are so familiar to map readers that their general distribution is sufficient information to recognize them (e.g., countries of the world). Typically, this method is used when it is more important for readers to ascertain the overall geographic pattern than to identify particular districts; if identification is needed, the individual geometric shapes are often labeled.

Mosaic cartograms

 
Mosaic cartogram of United States Electoral College results (scaled by 2008 electors) of four past Presidential elections (1996, 2000, 2004, 2008)
  States carried by the Republican in all four elections
  States carried by the Republican in three of the four elections
  States carried by each party twice in the four elections
  States carried by the Democrat in three of the four elections
  States carried by the Democrat in all four elections

In this approach (also called block or regular cartograms), each shape is not just scaled or warped, but is reconstructed from a discrete tessellation of space, usually into squares or hexagons. Each cell of the tessellation represents a constant value of the variable (e.g., 5000 residents), so the number of whole cells to be occupied can be calculated (although rounding error often means that the final area is not exactly proportional to the variable). Then a shape is assembled from those cells, usually with some attempt to retain the original shape, including salient features such as panhandles that aid recognition (for example, Long Island and Cape Cod are often exaggerated). Thus, these cartograms are usually homomorphic and at least partially contiguous.

This method works best with variables that are already measured as a relatively low-valued integer, enabling a one-to-one match with the cells. This has made them very popular for visualizing the United States Electoral College that determines the election of the president, appearing on television coverage and numerous vote-tracking websites.[27] Several examples of block cartograms were published during the 2016 U.S. presidential election season by The Washington Post,[28] the FiveThirtyEight blog,[29] and the Wall Street Journal,[30] among others.

The major disadvantage of this type of cartogram has traditionally been that they had to be constructed manually, but recently algorithms have been developed to automatically generate both square and hexagonal mosaic cartograms.[31][32] One of these, Tilegrams, even admits that the results of their algorithm is not perfect and provides a way for users to edit the product.

Linear cartograms

 
A linear cartogram of the London Underground, with distance distorted to represent travel time from High Barnet station

While an area cartogram manipulates the area of a polygon feature, a linear cartogram manipulates linear distance on a line feature. The spatial distortion allows the map reader to easily visualize intangible concepts such as travel time and connectivity on a network. Distance cartograms are also useful for comparing such concepts among different geographic features. A distance cartogram may also be called a central-point cartogram.

A common use of distance cartograms is to show the relative travel times and directions from vertices in a network. For example, on a distance cartogram showing travel time between cities, the less time required to get from one city to another, the shorter the distance on the cartogram will be. When it takes a longer time to travel between two cities, they will be shown as further apart in the cartogram, even if they are physically close together.

Distance cartograms are also used to show connectivity. This is common on subway and metro maps, where stations and stops are shown as being the same distance apart on the map even though the true distance varies. Though the exact time and distance from one location to another is distorted, these cartograms are still useful for travel and analysis.

Multivariate cartograms

 
Hexagonal mosaic cartogram of the results of the 2019 Canadian parliamentary election, colored with the party of each winner using a nominal choropleth technique.
Main article: Multivariate map

Both area and linear cartograms adjust the base geometry of the map, but neither has any requirements for how each feature is symbolized. This means that symbology can be used to represent a second variable using a different type of thematic mapping technique.[16] For linear cartograms, line width can be scaled as a flow map to represent a variable such as traffic volume. For area cartograms, it is very common to fill each district with a color as a choropleth map. For example, WorldMapper has used this technique to map topics relating to global social issues, such as poverty or malnutrition; a cartogram based on total population is combined with a choropleth of a socioeconomic variable, giving readers a clear visualization of the number of people living in underprivileged conditions.

Another option for diagrammatic cartograms is to subdivide the shapes as charts (commonly a pie chart), in the same fashion often done with proportional symbol maps. This can be very effective for showing complex variables such as population composition, but can be overwhelming if there are a large number of symbols or if the individual symbols are very small.

Production

One of the first cartographers to generate cartograms with the aid of computer visualization was Waldo Tobler of UC Santa Barbara in the 1960s. Prior to Tobler's work, cartograms were created by hand (as they occasionally still are). The National Center for Geographic Information and Analysis located on the UCSB campus maintains an online Cartogram Central with resources regarding cartograms.

A number of software packages generate cartograms. Most of the available cartogram generation tools work in conjunction with other GIS software tools as add-ons or independently produce cartographic outputs from GIS data formatted to work with commonly used GIS products. Examples of cartogram software include ScapeToad,[33][34] Cart,[35] and the Cartogram Processing Tool (an ArcScript for ESRI's ArcGIS), which all use the Gastner-Newman algorithm.[36][37] An alternative algorithm, Carto3F,[38] is also implemented as an independent program for non-commercial use on Windows platforms.[39] This program also provides an optimization to the original Dougenik rubber-sheet algorithm.[40][41] The CRAN package recmap provides an implementation of a rectangular cartogram algorithm.[42]

Algorithms

 
Cartogram (likely Gastner-Newman) showing Open Europe estimate of total European Union net budget expenditure in euros for the whole period 2007–2013, per capita, based on Eurostat 2007 pop. estimates (Luxembourg not shown).
Net contributors
  −5000 to −1000 euro per capita
  −1000 to −500 euro per capita
  −500 to 0 euro per capita
Net recipients
  0 to 500 euro per capita
  500 to 1000 euro per capita
  1000 to 5000 euro per capita
  5000 to 10000 euro per capita
  10000 euro plus per capita
Year Author Algorithm Type Shape preservation Topology preservation
1973 Tobler Rubber map method area contiguous with distortion Yes, but not guaranteed
1976 Olson Projector method area noncontiguous yes No
1978 Kadmon, Shlomi Polyfocal projection distance radial Unknown Unknown
1984 Selvin et al. DEMP (Radial Expansion) method area contiguous with distortion Unknown
1985 Dougenik et al. Rubber Sheet Distortion method [41] area contiguous with distortion Yes, but not guaranteed
1986 Tobler Pseudo-Cartogram method area contiguous with distortion Yes
1987 Snyder Magnifying glass azimuthal map projections distance radial Unknown Unknown
1989 Colette Cauvin [fr] et al. Piezopleth maps area contiguous with distortion Unknown
1990 Torguson Interactive polygon zipping method area contiguous with distortion Unknown
1990 Dorling Cellular Automata Machine method area contiguous with distortion Yes
1993 Gusein-Zade, Tikunov Line Integral method area contiguous with distortion Yes
1996 Dorling Circular cartogram area noncontiguous no (circles) No
1997 Sarkar, Brown Graphical fisheye views distance radial Unknown Unknown
1997 Edelsbrunner, Waupotitsch Combinatorial-based approach area contiguous with distortion Unknown
1998 Kocmoud, House Constraint-based approach area contiguous with distortion Yes
2001 Keim, North, Panse CartoDraw[43] area contiguous with distortion Yes, algorithmically guaranteed
2004 Gastner, Newman Diffusion-based method[44] area contiguous with distortion Yes, algorithmically guaranteed
2004 Sluga Lastna tehnika za izdelavo anamorfoz area contiguous with distortion Unknown
2004 van Kreveld, Speckmann Rectangular Cartogram[45] area contiguous no (rectangles) No
2004 Heilmann, Keim et al. RecMap[42] area noncontiguous no (rectangles) No
2005 Keim, North, Panse Medial-axis-based cartograms[46] area contiguous with distortion Yes, algorithmically guaranteed
2009 Heriques, Bação, Lobo Carto-SOM area contiguous with distortion Yes
2013 Shipeng Sun Opti-DCN[40] and Carto3F[38] area contiguous with distortion Yes, algorithmically guaranteed
2014 B. S. Daya Sagar Mathematical Morphology-Based Cartograms area contiguous with local distortion,
but no global distortion		 No
2018 Gastner, Seguy, More Fast Flow-Based Method[22] area contiguous with distortion Yes, algorithmically guaranteed

See also

References

  1. ^ a b Tobler, Waldo (March 2022). "Thirty-Five Years of Computer Cartograms". Annals of the Association of American Geographers. 94 (1): 58–73. CiteSeerX 10.1.1.551.7290. doi:10.1111/j.1467-8306.2004.09401004.x. JSTOR 3694068. S2CID 129840496.
  2. ^ a b Jacque Bertin, Sémiologie Graphique. Les diagrammes, les réseaux, les cartes. With Marc Barbut [et al.]. Paris : Gauthier-Villars. Semiology of Graphics, English Edition, Translation by William J. Berg, University of Wisconsin Press, 1983.)
  3. ^ Johnson (2008-12-08). "Early cartograms". indiemaps.com/blog. Retrieved 2012-08-17.
  4. ^ a b Levasseur, Pierre Émile (1876-08-29). "Memoire sur l'étude de la statistique dans l'enseignenent primaire, secondaire et superieur". Programme du Neuvieme Congrès international de Statistique, I. Section, Theorie et population: 7–32.. Unfortunately, all available scans did not expand the gatefold, so only one map in the series is visible online.
  5. ^ Haack, Hermann; Weichel, Hugo (1903). Kartogramm zur Reichstagswahl. Zwei Wahlkarten des Deutschen Reiches. Justus Perthes Gotha.
  6. ^ Hennig, Benjamin D. (Nov 2018). "Kartogramm zur Reichstagswahl: An Early Electoral Cartogram of Germany". The Bulletin of the Society of University Cartographers. 52 (2): 15–25.
  7. ^ Bailey, William B. (April 6, 1911). "Apportionment Map of the United States". The Independent. 70 (3253): 722.
  8. ^ "Electrical Importance of the Various States". Electrical World. 77 (12): 650–651. March 19, 1921.
  9. ^ a b Raisz, Erwin (Apr 1934). "The Rectangular Statistical Cartogram". Geographical Review. 24 (2): 292–296. doi:10.2307/208794. JSTOR 208794.
  10. ^ Raisz, Erwin (1936). "Rectangular Statistical Cartograms of the World". Journal of Geography. 34 (1): 8–10. doi:10.1080/00221343608987880.
  11. ^ Funkhouser, H. Gray (1937). "Historical Development of the Graphical Representation of Statistical Data". Osiris. 3: 259–404. doi:10.1086/368480. JSTOR 301591. S2CID 145013441.
  12. ^ Krygier, John. "More Old School Cartograms, 1921-1938". Making Maps: DIY Cartography. Retrieved 14 November 2020.
  13. ^ Raisz, Erwin, General Cartography, 2nd Edition, McGraw-Hill, 1948, p.257
  14. ^ Raisz, Erwin (1962). Principles of Cartography. McGraw-Hill. pp. 215–221.
  15. ^ a b c d Tobler, Waldo R. (Jan 1963). "Geographic Area and Map Projections". Geographical Review. 53 (1): 59–79. doi:10.2307/212809. JSTOR 212809.
  16. ^ a b c Dent, Borden D., Jeffrey S. Torguson, Thomas W. Hodler, Cartography: Thematic Map Design, 6th Edition, McGraw-Hill, 2009, pp.168-187
  17. ^ Nusrat, Sabrina; Kobourov, Stephen (2015). "Visualizing Cartograms: Goals and Task Taxonomy". 17th Eurographics Conference on Visualization (Eurovis). arXiv:1502.07792. Retrieved 15 November 2020.
  18. ^ a b Nusrat, Sabrina; Kobourov, Stephen (2016). "The State of the Art in Cartograms". Computer Graphics Forum. 35 (3): 619–642. arXiv:1605.08485. doi:10.1111/cgf.12932. hdl:10150/621282. S2CID 12180113. Special issue: 18th Eurographics Conference on Visualization (EuroVis), State of the Art Report
  19. ^ a b Markowska, Anna (2019). "Cartograms - classification and terminology". Polish Cartographical Review. 51 (2): 51–65. doi:10.2478/pcr-2019-0005.
  20. ^ Bortins, Ian; Demers, Steve. "Cartogram Types". Cartogram Central. National Center for Geographic Information Analysis, UC Santa Barbara. Retrieved 15 November 2020.
  21. ^ Tobler, Waldo R. (1973). "A Continuous Transformation Useful for Districting". Annals of the New York Academy of Sciences. 219 (1): 215–220. Bibcode:1973NYASA.219..215T. doi:10.1111/j.1749-6632.1973.tb41401.x. hdl:2027.42/71945. PMID 4518429. S2CID 35585206.
  22. ^ a b Michael T. Gastner; Vivien Seguy; Pratyush More (2018). "Fast flow-based algorithm for creating density-equalizing map projections". Proceedings of the National Academy of Sciences. 115 (10): E2156–E2164. arXiv:1802.07625. Bibcode:2018arXiv180207625G. doi:10.1073/pnas.1712674115. PMC 5877977. PMID 29463721.
  23. ^ Gastner, Michael T.; Newman, M.E.J. (May 18, 2004). "Diffusion-based Method for Producing Density-Equalizing Maps". Proceedings of the National Academy of Sciences of the United States of America. 101 (20): 7499–7504. arXiv:physics/0401102. doi:10.1073/pnas.0400280101. JSTOR 3372222. PMC 419634. PMID 15136719. S2CID 2487634.
  24. ^ Paull, John & Hennig, Benjamin (2016) Atlas of Organics: Four Maps of the World of Organic Agriculture Journal of Organics. 3(1): 25–32.
  25. ^ House, Donald H.; Kocmoud, Christopher J. (October 1998). "Continuous cartogram construction". Proceedings Visualization '98: 197–204. doi:10.1109/VISUAL.1998.745303. ISBN 0-8186-9176-X.
  26. ^ a b Dorling, Daniel (1996). Area Cartograms: Their Use and Creation. Concepts and Techniques in Modern Geography (CATMOG). Vol. 59. University of East Anglia.
  27. ^ Bliss, Laura; Patino, Marie. "How to Spot Misleading Election Maps". Bloomberg CityLab. Bloomberg. Retrieved 15 November 2020.
  28. ^ "Poll: Redrawing the Electoral Map". Washington Post. Retrieved 4 February 2018.
  29. ^ "2016 Election Forecast". FiveThirtyEight blog. Retrieved 4 February 2018.
  30. ^ "Draw the 2016 Electoral College Map". Wall Street Journal. Retrieved 4 February 2018.
  31. ^ Cano, R.G.; Buchin, K.; Castermans, T.; Pieterse, A.; Sonke, W.; Speckman, B. (2015). "Mosaic Drawings and Cartograms". Computer Graphics Forum. 34 (3): 361–370. doi:10.1111/cgf.12648. S2CID 41253089. Proceedings of 2015 Eurographics Conference on Visualization (EuroVis)
  32. ^ Florin, Adam; Hamel, Jessica. "Tilegrams". Pitch Interactive. Retrieved 15 November 2020.
  33. ^ ScapeToad
  34. ^ . Archived from the original on 2013-06-28. Retrieved 2012-08-17.
  35. ^ Cart: Computer software for making cartograms
  36. ^ Cartogram Geoprocessing Tool
  37. ^ Hennig, Benjamin D.; Pritchard, John; Ramsden, Mark; Dorling, Danny, "Remapping the World's Population: Visualizing data using cartograms", ArcUser (Winter 2010): 66–69
  38. ^ a b Sun, Shipeng (2013), "A Fast, Free-Form Rubber-Sheet Algorithm for Contiguous Area Cartograms", International Journal of Geographical Information Science, 27 (3): 567–93, doi:10.1080/13658816.2012.709247, S2CID 17216016
  39. ^ Personal Website of Shipeng Sun
  40. ^ a b Sun, Shipeng (2013), "An Optimized Rubber-Sheet Algorithm for Continuous Area Cartograms", The Professional Geographer, 16 (1): 16–30, doi:10.1080/00330124.2011.639613, S2CID 58909676
  41. ^ a b Dougenik, James A.; Chrisman, Nicholas R.; Niemeyer, Duane R. (1985), "An Algorithm to Construct Continuous Area Cartograms", The Professional Geographer, 37 (1): 75–81, doi:10.1111/j.0033-0124.1985.00075.x
  42. ^ a b Heilmann, Roland; Keim, Daniel; Panse, Christian; Sips, Mike (2004). RecMap : Rectangular Map Approximations. Proceedings of the 10th IEEE Symposium on Information Visualization. pp. 33–40. doi:10.1109/INFVIS.2004.57. ISBN 978-0-7803-8779-9. S2CID 14266549.
  43. ^ Keim, Daniel; North, Stephen; Panse, Christian (2004). "CartoDraw: a fast algorithm for generating contiguous cartograms". IEEE Trans Vis Comput Graph. 10 (1): 95–110. doi:10.1109/TVCG.2004.1260761. PMID 15382701. S2CID 9726148.
  44. ^ Gastner, Michael T. and Mark E. J. Newman, "Diffusion-based method for producing density-equalizing maps." Proceedings of the National Academy of Sciences 2004; 101: 7499–7504.
  45. ^ van Kreveld, Marc; Speckmann, Bettina (2004). On Rectangular Cartograms. In: Albers S., Radzik T. (Eds) Algorithms – ESA 2004. ESA 2004. Lecture Notes in Computer Science. Lecture Notes in Computer Science. Vol. 3221. pp. 724–735. doi:10.1007/978-3-540-30140-0_64. ISBN 978-3-540-23025-0.
  46. ^ Keim, Daniel; Panse, Christian; North, Stephen (2005). "Medial-axis-based cartograms". IEEE Computer Graphics and Applications. 25 (3): 60–68. doi:10.1109/MCG.2005.64. PMID 15943089. S2CID 6012366.

Further reading

  • Campbell, John. Map Use and Analysis. New York: McGraw-Hill, 2001.
  • Dorling, Daniel. "Area cartograms: Their use and creation." "Concepts and Techniques in Modern Geography series no. 59." Norwich: University of East Anglia, 1996.
  • Gastner, Michael T. and Mark E. J. Newman, "Diffusion-based method for producing density-equalizing maps." Proceedings of the National Academy of Sciences 2004; 101: 7499–7504.
  • Gillard, Quentin (1979). "Places in the News: The Use of Cartograms in Introductory Geography Courses". Journal of Geography. 78 (3): 114–115. doi:10.1080/00221347908979963.
  • Hennig, Benjamin D. "Cartograms." International Encyclopedia of Geography: People, the Earth, Environment and Technology. Hoboken, NJ: John Wiley & Sons (2021).
  • Hennig, Benjamin D. "Rediscovering the World: Map Transformations of Human and Physical Space." Berlin, Heidelberg: Springer, 2013.
  • House, Donald H. and Christopher Kocmoud, "Continuous Cartogram Construction." Proceedings of the IEEE Conference on Visualization 1998
  • Paull, John & Hennig, Benjamin (2016) Atlas of Organics: Four Maps of the World of Organic Agriculture Journal of Organics. 3(1): 25–32.
  • Tobler, Waldo. "Thirty-Five Years of Computer Cartograms." Annals of the Association of American Geographers. 94 (2004): 58–73.
  • Vescovo, Victor. "The Atlas of World Statistics." Dallas: Caladan Press, 2005.

External links

 
Wikimedia Commons has media related to Cartograms.
  • Cartogram Central
  • Worldmapper collection of world cartograms
  • Cartograms about Brazil
  • Tilegrams - Interactive tool for constructing hexagonal mosaic cartograms

January 13, 2023
cartogram, broader, coverage, this, topic, thematic, confused, with, cartography, cartogram, also, called, value, area, anamorphic, latter, common, among, german, speakers, thematic, features, countries, provinces, which, their, geographic, size, altered, dire. For broader coverage of this topic see Thematic map Not to be confused with Cartography A cartogram also called a value area map or an anamorphic map the latter common among German speakers is a thematic map of a set of features countries provinces etc in which their geographic size is altered to be directly proportional to a selected ratio level variable such as travel time population or GNP Geographic space itself is thus warped sometimes extremely in order to visualize the distribution of the variable It is one of the most abstract types of map in fact some forms may more properly be called diagrams They are primarily used to display emphasis and for analysis as nomographs 1 Mosaic cartogram showing the distribution of the global population Each of the 15 266 pixels represents the home country of 500 000 people cartogram by Max Roser for Our World in Data Cartograms leverage the fact that size is the most intuitive visual variable for representing a total amount 2 In this it is a strategy that is similar to proportional symbol maps which scale point features and many flow maps which scale the weight of linear features However these two techniques only scale the map symbol not space itself a map that stretches the length of linear features is considered a linear cartogram although additional flow map techniques may be added Once constructed cartograms are often used as a base for other thematic mapping techniques to visualize additional variables such as choropleth mapping Contents 1 History 2 General principles 3 Area cartograms 3 1 Anamorphic Projection 3 2 Shape warping contiguous cartograms 3 3 Non contiguous isomorphic cartograms 3 4 Diagrammatic Dorling cartograms 3 5 Mosaic cartograms 4 Linear cartograms 5 Multivariate cartograms 6 Production 6 1 Algorithms 7 See also 8 References 9 Further reading 10 External linksHistory Edit One of Levasseur s 1876 cartograms of Europe the earliest known published example of this technique The cartogram was developed later than other types of thematic maps but followed the same tradition of innovation in France 3 The earliest known cartogram was published in 1876 by French statistician and geographer Pierre Emile Levasseur who created a series of maps that represented the countries of Europe as squares sized according to a variable and arranged in their general geographical position with separate maps scaled by area population religious adherents and national budget 4 Later reviewers have called his figures a statistical diagram rather than a map but Levasseur referred to it as a carte figurative the common term then in use for any thematic map He produced them as teaching aids immediately recognizing the intuitive power of size as a visual variable It is impossible that the child is not struck by the importance of the trade of Western Europe in relation to that of Eastern Europe that he does not notice how much England which has a small territory but outweighs other nations by its wealth and especially by its navy how much on the contrary Russia which by its area and its population occupies the first rank is still left behind by other nations in the commerce and navigation Levasseur s technique does not appear to have been adopted by others and relatively few similar maps appear for many years The next notable development was a pair of maps by Hermann Haack and Hugo Weichel of the 1898 election results for the German Reichstag in preparation for the 1903 election the earliest known contiguous cartogram 5 Both maps showed a similar outline of the German Empire with one subdivided into constituencies to scale and the other distorting the constituencies by area The subsequent expansion of densely populated areas around Berlin Hamburg and Saxony was intended to visualize the controversial tendency of the mainly urban Social Democrats to win the popular vote while the mainly rural Zentrum won more seats thus presaging the modern popularity of cartograms for showing the same tendencies in recent elections in the United States 6 The continuous cartogram emerged soon after in the United States where a variety appeared in the popular media after 1911 7 8 Most were rather crudely drawn compared to Haack and Weichel with the exception of the rectangular statistical cartograms by the American master cartographer Erwin Raisz who claimed to have invented the technique 9 10 When Haack and Weichel referred to their map as a kartogramm this term was commonly being used to refer to all thematic maps especially in Europe 11 12 It was not until Raisz and other academic cartographers stated their preference for a restricted use of the term in their textbooks Raisz initially espousing value area cartogram that the current meaning was gradually adopted 13 14 The primary challenge of cartograms has always been the drafting of the distorted shapes making them a prime target for computer automation Waldo R Tobler developed one of the first algorithms in 1963 based on a strategy of warping space itself rather than the distinct districts 15 Since then a wide variety of algorithms have been developed see below although it is still common to craft cartograms manually 1 General principles EditSince the early days of the academic study of cartograms they have been compared to map projections in many ways in that both methods transform and thus distort space itself 15 The goal of designing a cartogram or a map projection is therefore to represent one or more aspects of geographic phenomena as accurately as possible while minimizing the collateral damage of distortion in other aspects In the case of cartograms by scaling features to have a size proportional to a variable other than their actual size the danger is that the features will be distorted to the degree that they are no longer recognizable to map readers making them less useful As with map projections the tradeoffs inherent in cartograms have led to a wide variety of strategies including manual methods and dozens of computer algorithms that produce very different results from the same source data The quality of each type of cartogram is typically judged on how accurately it scales each feature as well as on how and how well it attempts to preserve some form of recognizability in the features usually in two aspects shape and topological relationship i e retained adjacency of neighboring features 16 17 It is likely impossible to preserve both of these so some cartogram methods attempt to preserve one at the expense of the other some attempt a compromise solution of balancing the distortion of both and other methods do not attempt to preserve either one sacrificing all recognizability to achieve another goal Area cartograms Edit Cartogram of Germany with the states and districts resized according to population The area cartogram is by far the most common form it scales a set of region features usually administrative districts such as counties or countries such that the area of each district is directly proportional to a given variable Usually this variable represents the total count or amount of something such as total Population Gross domestic product or the number of retail outlets of a given brand or type Other strictly positive ratio variables can also be used such as GDP per capita or Birth rate but these can sometimes produce misleading results because of the natural tendency to interpret size as total amount 2 Of these total population is probably the most common variable sometimes called an isodemographic map The various strategies and algorithms have been classified a number of ways generally according to their strategies with respect to preserving shape and topology Those that preserve shape are sometimes called equiform although isomorphic same shape or homomorphic similar shape may be better terms Three broad categories are widely accepted contiguous preserve topology distort shape non contiguous preserve shape distort topology and diagrammatic distort both Recently more thorough taxonomies by Nusrat and Kobourov Markowska and others have built on this basic framework in an attempt to capture the variety in approaches that have been proposed and in the appearances of the results 18 19 The various taxonomies tend to agree on the following general types of area cartograms Anamorphic Projection Edit See also Anamorphosis This is a type of contiguous cartogram that uses a single parametric mathematical formula such as a polynomial curved surface to distort space itself to equalize the spatial distribution of the chosen variable rather than distorting the individual features Because of this distinction some have preferred to call the result a pseudo cartogram 20 Tobler s first computer cartogram algorithm was based on this strategy 15 21 for which he developed the general mathematical construct on which his and subsequent algorithms are based 15 This approach first models the distribution of the chosen variable as a continuous density function usually using a least squares fitting then uses the inverse of that function to adjust the space such that the density is equalized The Gastner Newman algorithm one of the most popular tools used today is a more advanced version of this approach 22 23 Because they do not directly scale the districts there is no guarantee that the area of each district is exactly equal to its value Shape warping contiguous cartograms Edit Contiguous cartogram Gastner Newman of the world with each country rescaled in proportion to the hectares of certified organic farming 24 Also called irregular cartograms or deformation cartograms 19 This is a family of very different algorithms that scale and deform the shape of each district while maintaining adjacent edges This approach has its roots in the early 20th Century cartograms of Haack and Weichel and others although these were rarely as mathematically precise as current computerized versions The variety of approaches that have been proposed include cellular automata quadtree partitions cartographic generalization medial axes spring like forces and simulations of inflation and deflation 18 Some attempt to preserve some semblance of the original shape and may thus be termed homomorphic 25 but these are often more complex and slower algorithms than those that severely distort shape Non contiguous isomorphic cartograms Edit Non contiguous isomorphic cartogram of the Czech Republic in which the size of each district is proportional to the Catholic percentage and the color choropleth representing the proportion voting for the KDU CSL party in 2010 showing a strong correlation This is perhaps the simplest method for constructing a cartogram in which each district is simply reduced or enlarged in size according to the variable without altering its shape at all 16 In most cases a second step adjusts the location of each shape to reduce gaps and overlaps between the shapes but their boundaries are not actually adjacent While the preservation of shape is a prime advantage of this approach the results often have a haphazard appearance because the individual districts do not fit together well Diagrammatic Dorling cartograms Edit Diagrammatic Dorling cartogram of the number of times each country is linked in the French language Wikipedia In this approach each district is replaced with a simple geometric shape of proportional size Thus the original shape is completely eliminated and contiguity may be retained in a limited form or not at all Although they are usually referred to as Dorling cartograms after Daniel Dorling s 1996 algorithm first facilitated their construction 26 these are actually the original form of cartogram dating back to Levasseur 1876 4 and Raisz 1934 9 Several options are available for the geometric shapes Circles Dorling typically brought together to be touching and arranged to retain some semblance of the overall shape of the original space 26 These often look like proportional symbol maps and some consider them to be a hybrid between the two types of thematic map Squares Levasseur Demers treated in much the same way as the circles although they do not generally fit together as simply Rectangles Raisz in which the height and width of each rectangular district is adjusted to fit within an overall shape The result looks much like a treemap diagram although the latter is generally sorted by size rather than geography These are often contiguous although the contiguity may be illusory because many of the districts that are adjacent in the map may not be the same as those that are adjacent in reality Because the districts are not at all recognizable this approach is most useful and popular for situations in which the shapes would not be familiar to map readers anyway e g U K parliamentary constituencies or where the districts are so familiar to map readers that their general distribution is sufficient information to recognize them e g countries of the world Typically this method is used when it is more important for readers to ascertain the overall geographic pattern than to identify particular districts if identification is needed the individual geometric shapes are often labeled Mosaic cartograms Edit Mosaic cartogram of United States Electoral College results scaled by 2008 electors of four past Presidential elections 1996 2000 2004 2008 States carried by the Republican in all four elections States carried by the Republican in three of the four elections States carried by each party twice in the four elections States carried by the Democrat in three of the four elections States carried by the Democrat in all four elections In this approach also called block or regular cartograms each shape is not just scaled or warped but is reconstructed from a discrete tessellation of space usually into squares or hexagons Each cell of the tessellation represents a constant value of the variable e g 5000 residents so the number of whole cells to be occupied can be calculated although rounding error often means that the final area is not exactly proportional to the variable Then a shape is assembled from those cells usually with some attempt to retain the original shape including salient features such as panhandles that aid recognition for example Long Island and Cape Cod are often exaggerated Thus these cartograms are usually homomorphic and at least partially contiguous This method works best with variables that are already measured as a relatively low valued integer enabling a one to one match with the cells This has made them very popular for visualizing the United States Electoral College that determines the election of the president appearing on television coverage and numerous vote tracking websites 27 Several examples of block cartograms were published during the 2016 U S presidential election season by The Washington Post 28 the FiveThirtyEight blog 29 and the Wall Street Journal 30 among others The major disadvantage of this type of cartogram has traditionally been that they had to be constructed manually but recently algorithms have been developed to automatically generate both square and hexagonal mosaic cartograms 31 32 One of these Tilegrams even admits that the results of their algorithm is not perfect and provides a way for users to edit the product Linear cartograms Edit A linear cartogram of the London Underground with distance distorted to represent travel time from High Barnet station While an area cartogram manipulates the area of a polygon feature a linear cartogram manipulates linear distance on a line feature The spatial distortion allows the map reader to easily visualize intangible concepts such as travel time and connectivity on a network Distance cartograms are also useful for comparing such concepts among different geographic features A distance cartogram may also be called a central point cartogram A common use of distance cartograms is to show the relative travel times and directions from vertices in a network For example on a distance cartogram showing travel time between cities the less time required to get from one city to another the shorter the distance on the cartogram will be When it takes a longer time to travel between two cities they will be shown as further apart in the cartogram even if they are physically close together Distance cartograms are also used to show connectivity This is common on subway and metro maps where stations and stops are shown as being the same distance apart on the map even though the true distance varies Though the exact time and distance from one location to another is distorted these cartograms are still useful for travel and analysis Multivariate cartograms Edit Hexagonal mosaic cartogram of the results of the 2019 Canadian parliamentary election colored with the party of each winner using a nominal choropleth technique Main article Multivariate map Both area and linear cartograms adjust the base geometry of the map but neither has any requirements for how each feature is symbolized This means that symbology can be used to represent a second variable using a different type of thematic mapping technique 16 For linear cartograms line width can be scaled as a flow map to represent a variable such as traffic volume For area cartograms it is very common to fill each district with a color as a choropleth map For example WorldMapper has used this technique to map topics relating to global social issues such as poverty or malnutrition a cartogram based on total population is combined with a choropleth of a socioeconomic variable giving readers a clear visualization of the number of people living in underprivileged conditions Another option for diagrammatic cartograms is to subdivide the shapes as charts commonly a pie chart in the same fashion often done with proportional symbol maps This can be very effective for showing complex variables such as population composition but can be overwhelming if there are a large number of symbols or if the individual symbols are very small Production EditOne of the first cartographers to generate cartograms with the aid of computer visualization was Waldo Tobler of UC Santa Barbara in the 1960s Prior to Tobler s work cartograms were created by hand as they occasionally still are The National Center for Geographic Information and Analysis located on the UCSB campus maintains an online Cartogram Central with resources regarding cartograms A number of software packages generate cartograms Most of the available cartogram generation tools work in conjunction with other GIS software tools as add ons or independently produce cartographic outputs from GIS data formatted to work with commonly used GIS products Examples of cartogram software include ScapeToad 33 34 Cart 35 and the Cartogram Processing Tool an ArcScript for ESRI s ArcGIS which all use the Gastner Newman algorithm 36 37 An alternative algorithm Carto3F 38 is also implemented as an independent program for non commercial use on Windows platforms 39 This program also provides an optimization to the original Dougenik rubber sheet algorithm 40 41 The CRAN package recmap provides an implementation of a rectangular cartogram algorithm 42 Algorithms Edit Cartogram likely Gastner Newman showing Open Europe estimate of total European Union net budget expenditure in euros for the whole period 2007 2013 per capita based on Eurostat 2007 pop estimates Luxembourg not shown Net contributors 5000 to 1000 euro per capita 1000 to 500 euro per capita 500 to 0 euro per capita Net recipients 0 to 500 euro per capita 500 to 1000 euro per capita 1000 to 5000 euro per capita 5000 to 10000 euro per capita 10000 euro plus per capita Year Author Algorithm Type Shape preservation Topology preservation1973 Tobler Rubber map method area contiguous with distortion Yes but not guaranteed1976 Olson Projector method area noncontiguous yes No1978 Kadmon Shlomi Polyfocal projection distance radial Unknown Unknown1984 Selvin et al DEMP Radial Expansion method area contiguous with distortion Unknown1985 Dougenik et al Rubber Sheet Distortion method 41 area contiguous with distortion Yes but not guaranteed1986 Tobler Pseudo Cartogram method area contiguous with distortion Yes1987 Snyder Magnifying glass azimuthal map projections distance radial Unknown Unknown1989 Colette Cauvin fr et al Piezopleth maps area contiguous with distortion Unknown1990 Torguson Interactive polygon zipping method area contiguous with distortion Unknown1990 Dorling Cellular Automata Machine method area contiguous with distortion Yes1993 Gusein Zade Tikunov Line Integral method area contiguous with distortion Yes1996 Dorling Circular cartogram area noncontiguous no circles No1997 Sarkar Brown Graphical fisheye views distance radial Unknown Unknown1997 Edelsbrunner Waupotitsch Combinatorial based approach area contiguous with distortion Unknown1998 Kocmoud House Constraint based approach area contiguous with distortion Yes2001 Keim North Panse CartoDraw 43 area contiguous with distortion Yes algorithmically guaranteed2004 Gastner Newman Diffusion based method 44 area contiguous with distortion Yes algorithmically guaranteed2004 Sluga Lastna tehnika za izdelavo anamorfoz area contiguous with distortion Unknown2004 van Kreveld Speckmann Rectangular Cartogram 45 area contiguous no rectangles No2004 Heilmann Keim et al RecMap 42 area noncontiguous no rectangles No2005 Keim North Panse Medial axis based cartograms 46 area contiguous with distortion Yes algorithmically guaranteed2009 Heriques Bacao Lobo Carto SOM area contiguous with distortion Yes2013 Shipeng Sun Opti DCN 40 and Carto3F 38 area contiguous with distortion Yes algorithmically guaranteed2014 B S Daya Sagar Mathematical Morphology Based Cartograms area contiguous with local distortion but no global distortion No2018 Gastner Seguy More Fast Flow Based Method 22 area contiguous with distortion Yes algorithmically guaranteedSee also EditChoropleth map Type of data visualization for geographic regions Contour map Curve along which a 3 D surface is at equal elevation Thematic map Type of map that visualizes data Waldo ToblerReferences Edit a b Tobler Waldo March 2022 Thirty Five Years of Computer Cartograms Annals of the Association of American Geographers 94 1 58 73 CiteSeerX 10 1 1 551 7290 doi 10 1111 j 1467 8306 2004 09401004 x JSTOR 3694068 S2CID 129840496 a b Jacque Bertin Semiologie Graphique Les diagrammes les reseaux les cartes With Marc Barbut et al Paris Gauthier Villars Semiology of Graphics English Edition Translation by William J Berg University of Wisconsin Press 1983 Johnson 2008 12 08 Early cartograms indiemaps com blog Retrieved 2012 08 17 a b Levasseur Pierre Emile 1876 08 29 Memoire sur l etude de la statistique dans l enseignenent primaire secondaire et superieur Programme du Neuvieme Congres international de Statistique I Section Theorie et population 7 32 Unfortunately all available scans did not expand the gatefold so only one map in the series is visible online Haack Hermann Weichel Hugo 1903 Kartogramm zur Reichstagswahl Zwei Wahlkarten des Deutschen Reiches Justus Perthes Gotha Hennig Benjamin D Nov 2018 Kartogramm zur Reichstagswahl An Early Electoral Cartogram of Germany The Bulletin of the Society of University Cartographers 52 2 15 25 Bailey William B April 6 1911 Apportionment Map of the United States The Independent 70 3253 722 Electrical Importance of the Various States Electrical World 77 12 650 651 March 19 1921 a b Raisz Erwin Apr 1934 The Rectangular Statistical Cartogram Geographical Review 24 2 292 296 doi 10 2307 208794 JSTOR 208794 Raisz Erwin 1936 Rectangular Statistical Cartograms of the World Journal of Geography 34 1 8 10 doi 10 1080 00221343608987880 Funkhouser H Gray 1937 Historical Development of the Graphical Representation of Statistical Data Osiris 3 259 404 doi 10 1086 368480 JSTOR 301591 S2CID 145013441 Krygier John More Old School Cartograms 1921 1938 Making Maps DIY Cartography Retrieved 14 November 2020 Raisz Erwin General Cartography 2nd Edition McGraw Hill 1948 p 257 Raisz Erwin 1962 Principles of Cartography McGraw Hill pp 215 221 a b c d Tobler Waldo R Jan 1963 Geographic Area and Map Projections Geographical Review 53 1 59 79 doi 10 2307 212809 JSTOR 212809 a b c Dent Borden D Jeffrey S Torguson Thomas W Hodler Cartography Thematic Map Design 6th Edition McGraw Hill 2009 pp 168 187 Nusrat Sabrina Kobourov Stephen 2015 Visualizing Cartograms Goals and Task Taxonomy 17th Eurographics Conference on Visualization Eurovis arXiv 1502 07792 Retrieved 15 November 2020 a b Nusrat Sabrina Kobourov Stephen 2016 The State of the Art in Cartograms Computer Graphics Forum 35 3 619 642 arXiv 1605 08485 doi 10 1111 cgf 12932 hdl 10150 621282 S2CID 12180113 Special issue 18th Eurographics Conference on Visualization EuroVis State of the Art Report a b Markowska Anna 2019 Cartograms classification and terminology Polish Cartographical Review 51 2 51 65 doi 10 2478 pcr 2019 0005 Bortins Ian Demers Steve Cartogram Types Cartogram Central National Center for Geographic Information Analysis UC Santa Barbara Retrieved 15 November 2020 Tobler Waldo R 1973 A Continuous Transformation Useful for Districting Annals of the New York Academy of Sciences 219 1 215 220 Bibcode 1973NYASA 219 215T doi 10 1111 j 1749 6632 1973 tb41401 x hdl 2027 42 71945 PMID 4518429 S2CID 35585206 a b Michael T Gastner Vivien Seguy Pratyush More 2018 Fast flow based algorithm for creating density equalizing map projections Proceedings of the National Academy of Sciences 115 10 E2156 E2164 arXiv 1802 07625 Bibcode 2018arXiv180207625G doi 10 1073 pnas 1712674115 PMC 5877977 PMID 29463721 Gastner Michael T Newman M E J May 18 2004 Diffusion based Method for Producing Density Equalizing Maps Proceedings of the National Academy of Sciences of the United States of America 101 20 7499 7504 arXiv physics 0401102 doi 10 1073 pnas 0400280101 JSTOR 3372222 PMC 419634 PMID 15136719 S2CID 2487634 Paull John amp Hennig Benjamin 2016 Atlas of Organics Four Maps of the World of Organic Agriculture Journal of Organics 3 1 25 32 House Donald H Kocmoud Christopher J October 1998 Continuous cartogram construction Proceedings Visualization 98 197 204 doi 10 1109 VISUAL 1998 745303 ISBN 0 8186 9176 X a b Dorling Daniel 1996 Area Cartograms Their Use and Creation Concepts and Techniques in Modern Geography CATMOG Vol 59 University of East Anglia Bliss Laura Patino Marie How to Spot Misleading Election Maps Bloomberg CityLab Bloomberg Retrieved 15 November 2020 Poll Redrawing the Electoral Map Washington Post Retrieved 4 February 2018 2016 Election Forecast FiveThirtyEight blog Retrieved 4 February 2018 Draw the 2016 Electoral College Map Wall Street Journal Retrieved 4 February 2018 Cano R G Buchin K Castermans T Pieterse A Sonke W Speckman B 2015 Mosaic Drawings and Cartograms Computer Graphics Forum 34 3 361 370 doi 10 1111 cgf 12648 S2CID 41253089 Proceedings of 2015 Eurographics Conference on Visualization EuroVis Florin Adam Hamel Jessica Tilegrams Pitch Interactive Retrieved 15 November 2020 ScapeToad The Art of Software Cartogram Crash Course Archived from the original on 2013 06 28 Retrieved 2012 08 17 Cart Computer software for making cartograms Cartogram Geoprocessing Tool Hennig Benjamin D Pritchard John Ramsden Mark Dorling Danny Remapping the World s Population Visualizing data using cartograms ArcUser Winter 2010 66 69 a b Sun Shipeng 2013 A Fast Free Form Rubber Sheet Algorithm for Contiguous Area Cartograms International Journal of Geographical Information Science 27 3 567 93 doi 10 1080 13658816 2012 709247 S2CID 17216016 Personal Website of Shipeng Sun a b Sun Shipeng 2013 An Optimized Rubber Sheet Algorithm for Continuous Area Cartograms The Professional Geographer 16 1 16 30 doi 10 1080 00330124 2011 639613 S2CID 58909676 a b Dougenik James A Chrisman Nicholas R Niemeyer Duane R 1985 An Algorithm to Construct Continuous Area Cartograms The Professional Geographer 37 1 75 81 doi 10 1111 j 0033 0124 1985 00075 x a b Heilmann Roland Keim Daniel Panse Christian Sips Mike 2004 RecMap Rectangular Map Approximations Proceedings of the 10th IEEE Symposium on Information Visualization pp 33 40 doi 10 1109 INFVIS 2004 57 ISBN 978 0 7803 8779 9 S2CID 14266549 Keim Daniel North Stephen Panse Christian 2004 CartoDraw a fast algorithm for generating contiguous cartograms IEEE Trans Vis Comput Graph 10 1 95 110 doi 10 1109 TVCG 2004 1260761 PMID 15382701 S2CID 9726148 Gastner Michael T and Mark E J Newman Diffusion based method for producing density equalizing maps Proceedings of the National Academy of Sciences 2004 101 7499 7504 van Kreveld Marc Speckmann Bettina 2004 On Rectangular Cartograms In Albers S Radzik T Eds Algorithms ESA 2004 ESA 2004 Lecture Notes in Computer Science Lecture Notes in Computer Science Vol 3221 pp 724 735 doi 10 1007 978 3 540 30140 0 64 ISBN 978 3 540 23025 0 Keim Daniel Panse Christian North Stephen 2005 Medial axis based cartograms IEEE Computer Graphics and Applications 25 3 60 68 doi 10 1109 MCG 2005 64 PMID 15943089 S2CID 6012366 Further reading EditCampbell John Map Use and Analysis New York McGraw Hill 2001 Dorling Daniel Area cartograms Their use and creation Concepts and Techniques in Modern Geography series no 59 Norwich University of East Anglia 1996 Gastner Michael T and Mark E J Newman Diffusion based method for producing density equalizing maps Proceedings of the National Academy of Sciences 2004 101 7499 7504 Gillard Quentin 1979 Places in the News The Use of Cartograms in Introductory Geography Courses Journal of Geography 78 3 114 115 doi 10 1080 00221347908979963 Hennig Benjamin D Cartograms International Encyclopedia of Geography People the Earth Environment and Technology Hoboken NJ John Wiley amp Sons 2021 Hennig Benjamin D Rediscovering the World Map Transformations of Human and Physical Space Berlin Heidelberg Springer 2013 House Donald H and Christopher Kocmoud Continuous Cartogram Construction Proceedings of the IEEE Conference on Visualization 1998 Paull John amp Hennig Benjamin 2016 Atlas of Organics Four Maps of the World of Organic Agriculture Journal of Organics 3 1 25 32 Tobler Waldo Thirty Five Years of Computer Cartograms Annals of the Association of American Geographers 94 2004 58 73 Vescovo Victor The Atlas of World Statistics Dallas Caladan Press 2005 External links Edit Wikimedia Commons has media related to Cartograms Cartogram Central Worldmapper collection of world cartograms Classified Ads on the French Leboncoin social web site and their regional distribution Cartograms about Brazil Tilegrams Interactive tool for constructing hexagonal mosaic cartograms Retrieved from https en wikipedia org w index php title Cartogram amp oldid 1129901382, wikipedia, wiki, book, books, library,

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