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Abstract

Urban growth can take different forms, such as infill, expansion and leapfrog development. Here we focus on leapfrogging, which is characterised as new urban development bypassing vacant land. Analysing a sample of 100 global locations, we study the probability that land cover is converted from non-urban to urban as a function of the minimum distance to existing urban cells. The probability decreases with the distance but in many of the considered real-world samples it increases again just before the maximum possible distance. Comparing these empirical findings with numerical ones from a gravitational model, we discover that the characteristic increase can be found in both. Our results indicate that the conversion probability as a function of the distance to urban land cover includes three urban growth domains. (i) Expansion of existing settlements, (ii) discontinuous development of coincidental new settlements rather close to existing ones and (iii) leapfrogging of new settlements far away from existing ones. We conclude that gravitational effects can explain discontinuous development but leapfrogging can be attributed to a scarcity of developable land at long distances to settlements.

Keywords

Urban growth leapfrogging urban land cover probability simulation

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References

Angel

Parent

Civco

(2012) The fragmentation of urban landscapes: Global evidence of a key attribute of the spatial structure of cities, 1990–2000. Environment and Urbanization 24(1): 249–283.

Angel

Sheppard

Civco

, et al. (2005) The dynamics of global urban expansion. Working Paper 35563, The World Bank. (Accessed 4th March 2021). Available at: http://documents.worldbank.org/curated/en/138671468161635731/The-dynamics-of-global-urban-expansion

Archer

(1973) Land speculation and scattered development; failures in the urban-fringe land market. Urban Studies 10(3): 367–372.

Bahl

(1968) A land speculation model: The role of the property tax as a constraint to urban sprawl. Journal of Regional Science 8(2): 199–208.

Behnisch

Schorcht

Kriewald

, et al. (2019) Settlement percolation: A study of building connectivity and poles of inaccessibility. Landscape and Urban Planning 191: 103631.

Benguigui

Czamanski

(2004) Simulation analysis of the fractality of cities. Geographical Analysis 36(1): 69–84.

Bontemps

Boettcher

Brockmann

, et al. (2015) Multi-year global land cover mapping at 300 m and characterization for climate modelling: Achievements of the land cover component of the ESA Climate Change Initiative. ISPRS – International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XL-7/W3: 323–328.

Broitman

Czamanski

(2012) Cities in competition, characteristic time, and leapfrogging developers. Environment and Planning B: Planning and Design 39(6): 1105–1118.

Chen

Zhang

Liu

, et al. (2014) The global pattern of urbanization and economic growth: Evidence from the last three decades. PloS One 9(8): e103799.

10.

Chen

Irwin

Jayaprakash

, et al. (2017) Market thinness, income sorting and leapfrog development across the urban–rural gradient. Regional Science and Urban Economics 66: 213–223.

11.

Christaller

(1966) Central Places in Southern Germany. London: Prentice-Hall International, Inc. (Transl. from “Die zentralen Orte in Süddeutschland” by C. W. Baskin).

12.

Cohen

(2005) Urbanization in developing countries: Current trends, future projections, and key challenges for sustainability. Technology in Society 28(1–2): 63–80.

13.

Czamanski

Roth

(2011) Characteristic time, developers’ behavior and leapfrogging dynamics of high-rise buildings. The Annals of Regional Science 46(1): 101–118.

14.

Dietzel

Clarke

(2007) Toward optimal calibration of the sleuth land use change model. Transactions in GIS 11(1): 29–45.

15.

European Space Agency (ESA) (2017) Land Cover CCI Product User Guide Version 2. Technical Report. Available at: maps.elie.ucl.ac.be/CCI/viewer/download/ESACCI-LC-Ph2-PUGv2_2.0.pdf (accessed 4th March 2021).

16.

Ewing

(1994) Characteristics, causes, and effects of sprawl: A literature review. Environmental and Urban Studies 21(2): 1–15.

17.

Fluschnik

Kriewald

Ros

AGC

, et al. (2016) The size distribution, scaling properties and spatial organization of urban clusters: A global and regional percolation perspective. ISPRS International Journal of Geo-Information 5(7): 110.

18.

Fujita

Krugman

Venables

(1999) The Spatial Economy: Cities, Regions, and International Trade. Cambridge, MA: MIT press.

19.

Harris

Ullman

(1945) The nature of cities. The Annals of the American Academy of Political and Social Science 242(1): 7–17.

20.

Harvey

Clark

WAV

(1965) The nature and economics of urban sprawl. Land Economics 41(1): 1–9.

21.

Heim

(2001) Leapfrogging, urban sprawl, and growth management: Phoenix, 1950–2000. The American Journal of Economics and Sociology 60(1): 245–283.

22.

Hennemann

Rybski

Liefner

(2012) The myth of global science collaboration – Collaboration patterns in epistemic communities. Journal of Informetrics 6(2): 217–225.

23.

Jiang

O’Neill

(2017) Global urbanization projections for the shared socioeconomic pathways. Global Environmental Change 42: 193–199.

24.

Kim

Batty

(2011) Calibrating cellular automata models for simulating urban growth: Comparative analysis of SLEUTH and Metronamica. Working Paper 176, UCL Centre for Advanced Spatial Analysis. Available at: https://www.ucl.ac.uk/bartlett/casa/sites/bartlett/files/migrated-files/paper176.pdf (accessed 4th March 2021).

25.

, WBGU – German Advisory Council on Global Change (2016): Humanity on the move: Unlocking the transformative power of cities. http://pure.iiasa.ac.at/id/eprint/12906/ (accessed 4th March 2021).

26.

Kriewald

Fluschnik

Reusser

, et al. (2019) osc: Orthodromic Spatial Clustering. R package version 1.0.4. (Accessed 4th March 2021).Available at: https://CRAN.R-project.org/package=osc

27.

Rybski

Kropp

(2021) Singularity cities. Environment and Planning B: Urban Analytics and City Science 48(1): 43–59.

28.

Mills

(1981) Growth, speculation and sprawl in a monocentric city. Journal of Urban Economics 10(2): 201–226.

29.

Peiser

(1989) Density and urban sprawl. Land Economics 65(3): 193–204.

30.

Rybski

Ros

AGC

Kropp

(2013) Distance weighted city growth. Physical Review E, Statistical, Nonlinear, and Soft Matter Physics 87(4): 042114.

31.

Silva

Clarke

(2002) Calibration of the sleuth urban growth model for Lisbon and Porto, Portugal. Computers, Environment and Urban System 26(6): 525–552.

32.

Sun

Zhao

(2018) Spatiotemporal dynamics of urban expansion in 13 cities across the Jing-Jin-Ji urban agglomeration from 1978 to 2015. Ecological Indicators 87: 302–313.

33.

Taubenböck

Esch

Felbier

, et al. (2012) Monitoring urbanization in mega cities from space. Remote Sensing of Environment 117: 162–176.

34.

Ullman

(1941) A theory of location for cities. American Journal of Sociology 46(6): 853–864.

35.

UNEP-WCMC and IUCN (2019) Protected planet: The world database on protected areas, January 2019. Available at: www.protectedplanet.net (accessed 4th March 2021).

36.

(2002) Calibration of stochastic cellular automata: The application to rural-urban land conversions. International Journal of Geographical Information Science 16(8): 795–818.

37.

Zhang

Wrenn

Irwin

(2017) Spatial heterogeneity, accessibility, and zoning: An empirical investigation of leapfrog development. Journal of Economic Geography 17(3): 547–570.

38.

Zhao

Zhou

Zhu

, et al. (2015) Rates and patterns of urban expansion in China’s 32 major cities over the past three decades. Landscape Ecology 30(8): 1541–1559.

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Quantitative evidence for leapfrogging in urban growth

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