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Abstract

Even though the past three decades have seen numerous crucial investigations on interurban scaling characteristics, there has been less focus on revealing multiscale properties within municipal or metropolitan structures. We demonstrate how a newly developed methodology, the Geographically Weighted Multiscale Analysis (GWMSA) stemming from the theory of multifractal systems, can be used to analyze small-scale urban environments with respect to their intermittency and roughness simultaneously. To this end, apart from the widely used sand-box method, we introduce wavelet coefficients in the multiscale analysis of urban systems. In more detail, the spatially continuous scanning of the three largest French conurbations—Paris, Marseille, and Lyon—over their territories and at length scales ranging from parcel to neighborhood level will allow to derive and compare globally and locally characteristic scaling exponents. Depending on the feature under analysis, the exponents reveal qualitatively distinct structural properties, whereby the viability of our findings is further verified on four exemplary typologies of multiscale behavior in urban systems. To introduce GWMSA, this paper focuses primarily on morphological characteristics and findings provide a compelling alternative to how we capture and define district-scale spatial organization and interdependencies within urban settlements.

Keywords

French conurbations wavelet coefficient multifractal systems intermittency roughness

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References

Ahlfeldt

Pietrostefani

(2017) The Compact City in Empirical Research: A Quantitative Literature Review. Spatial Economics Research Centre, London School of Economics and Political Science.: SERC discussion paper, 215.

Ariza-Villaverde

Jiménez-Hornero

De Ravé

, et al. (2013) Multifractal analysis of axial maps applied to the study of urban morphology. Computers, Environment and Urban Systems 38: 1–10.

Batty

Longley

(1994) Fractal Cities: A Geometry of Form and Function. Academic Press.

BD TOPO (2021) https://geoservices.ign.fr/documentation/diffusion/telechargement-donnees-libres.html#bd-topo

Brunsdon

Fotheringham

Charlton

, et al. (1996) Geographically weighted regression: a method for exploring spatial nonstationarity. Geographical Analysis 28(4): 281–298.

Chen

(2014) Multifractals of central place systems: Models, dimension spectrums, and empirical analysis. Physica A: Statistical Mechanics and Its Applications 402: 266–282.

Chen

(2019) Fractal dimension analysis of urban morphology based on spatial correlation functions. The Mathematics of Urban Morphology. Springer, Birkhäuser, Cham, pp. 21-53.

Chen

Wang

(2013) Multifractal characterization of urban form and growth: the case of Beijing. Environment and Planning B: Planning and Design 40(5): 884–904.

Chen

Zhou

(2003) The rank-size rule and fractal hierarchies of cities: mathematical models and empirical analyses. Environment and Planning B: Planning and Design 30(6): 799–818.

10.

Couloigner

Ranchin

(1998) Extraction of urban network from high-spatial-resolution imagery using multiresolution analysis and wavelet transform. In: Wavelet Applications in Signal and Imaging Processing VI. International Society for Optics and Photonics 3458: 103–112.

11.

Decoster

Roux

Arneodo

, et al. (2000) A wavelet-based method for multifractal image analysis. II. Applications to synthetic multifractal rough surfaces. The European Physical Journal B-Condensed Matter and Complex Systems 15(4): 739–764.

12.

Fleischmann

Romice

Porta

, et al. (2020) Measuring urban form: overcoming terminological inconsistencies for a quantitative and comprehensive morphologic analysis of cities. Environment and Planning B: Urban Analytics and City Science 48: 2399808320910444–2399808320912150.

13.

Frankhauser

(1998) The fractal approach. a new tool for the spatial analysis of urban agglomerations. Population: An English Selection 10: 205–240.

14.

Gan

MKP

(2017) K-means clustering with outlier removal. Pattern Recognition Letters 90: 8–14.

15.

Grassberger

Procaccia

(2004) Measuring the strangeness of strange attractors. In: The Theory of Chaotic Attractors. Springer.

16.

Cheng

Wang

, et al. (2012) Multifractal characterization of urban residential land price in space and time. Applied Geography 34: 161–170.

17.

Huang

Zhang

(2012) A multiscale urban complexity index based on 3d wavelet transform for spectral– spatial feature extraction and classification: an evaluation on the 8-channel WorldView-2 imagery. International Journal of Remote Sensing 33(8): 2641–2656.

18.

INSEE (2021) https://www.insee.fr/. Visited on 2021-07-22.

19.

Kang

Tong

, et al. (2012) Intra-urban human mobility patterns: an urban morphology perspective. Physica A: Statistical Mechanics and Its Applications 391(4): 1702–1717.

20.

Krim

Indekeu

(1993) Roughness exponents: a paradox resolved. Physical Review E 48(2): 1576–1578.

21.

Krizek

Johnson

(2006) Proximity to trails and retail: effects on urban cycling and walking. Journal of the American Planning Association 72(1): 33–42. DOI:10.1080/01944360608976722.

22.

Lagarias

Prastacos

(2020) Comparing the urban form of South European cities using fractal dimensions. Environment and Planning B: Urban Analytics and City Science 47(7): 1149–1166.

23.

Larsen

El-Geneidy

Yasmin

(2010) Beyond the Quarter Mile: Examining Travel Distances by Walking and Cycling. Montre´al.

24.

Lee

Yamamoto

(1994) Wavelet analysis: theory and applications. Hewlett Packard Journal 45: 44–44.

25.

Lengyel

Alvanides

Friedrich

(2022) Modelling the interdependence of spatial scales in urban systems. Environment and Planning B: Urban Analytics and City Science. Available at: https://doi.org/10.1177/23998083221091569

26.

Tang

(2004) Fractal dimension of a transportation network and its relationship with urban growth: a study of the Dallas-Fort Worth area. Environment and Planning B: Planning and Design 31(6): 895–911.

27.

Mandelbrot

(1975) Stochastic models for the Earth’s relief, the shape and the fractal dimension of the coastlines, and the number-area rule for islands. Proceedings of the National Academy of Sciences 72(10): 3825–3828.

28.

Mandelbrot

Van Ness

(1968) Fractional Brownian motions, fractional noises and applications. SIAM Review 10(4): 422–437.

29.

Manson

(2007) Challenges in evaluating models of geographic complexity. Environment and Planning B: Planning and Design 34(2): 245–260.

30.

Ortman

Lobo

Smith

(2020) Cities: complexity, theory and history. Plos One 15(12): e0243621.

31.

Raimbault

(2018) Calibration of a density-based model of urban morphogenesis. PloS One 13(9): e0203516.

32.

Rybski

Arcaute

Batty

(2019) Urban scaling laws.

33.

Salat

Murcio

Yano

, et al. (2018) Uncovering inequality through multifractality of land prices: 1912 and contemporary kyoto. Plos One 13(4): e0196737.

34.

Salat

Bourdic

Nowacki

, et al. (2010) Assessing urban complexity. International Journal of Sustainable Building Technology and Urban Development 1(2): 160–167.

35.

Schirmer

Axhausen

(2016) A multiscale classification of urban morphology. Journal of Transport and Land Use 9(1): 101–130.

36.

Sémécurbe

Tannier

Roux

, et al. (2019) Applying two fractal methods to characterise the local and global deviations from scale invariance of built patterns throughout mainland France. Journal of Geographical Systems 21(2): 271–293.

37.

Shi

(2010) Selection of bandwidth type and adjustment side in kernel density estimation over inhomogeneous backgrounds. International Journal of Geographical Information Science 24(5): 643–660.

38.

Tannier

Vuidel

Houot

, et al. (2012) Spatial accessibility to amenities in fractal and nonfractal urban patterns. Environment and Planning B: Planning and Design 39(5): 801–819.

39.

Tél

Fülöp

Vicsek

et al. (1989) Determination of fractal dimensions for geometrical multifractals. Physica A: Statistical Mechanics and Its Applications 159(2): 155–166.

40.

Terzi

Kaya

(2011) dynamic spatial analysis of urban sprawl through fractal geometry: the case of Istanbul. Environment and Planning B: Planning and Design 38(1): 175–190.

41.

Urban unit (2020) https://www.insee.fr/fr/information/4802589. Visited on 2021-07-29

42.

Vega Orozco

Golay

Kanevski

(2015) Multifractal portrayal of the Swiss population.Cybergeo: European Journal of Geography.

43.

Wendt

Roux

Jaffard

, et al. (2009) Wavelet leaders and bootstrap for multifractal analysis of images. Signal Processing 89(6): 1100–1114.

44.

Tan

Guo

, et al. (2020) Multi-scale identification of urban landscape structure based on two-dimensional wavelet analysis: The case of metropolitan Beijing, china. Ecological Complexity 43: 100832.

45.

, et al. (2020) Scaling laws in intra-urban systems and over time at the district level in shanghai, china. Physica A: Statistical Mechanics and Its Applications 560: 125162.

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Roughness and intermittency within metropolitan regions - Application in three French conurbations

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