Functional Topology of Evolving Urban Drainage Networks

Yang, Se Hwan; Paik, Kyungrock; McGrath, Gavan; Urich, Christian; Krueger, Elisabeth; Kumar, Praveen; Rao, P. Suresh C.

doi:10.1002/2017wr021555

Cited by 36 publications

(36 citation statements)

References 53 publications

(63 reference statements)

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“…Similar effects of urban expansion and densification on the power-law node degree observed is observed in several urban infrastructure systems such as roads and sewage networks (Mohajeri et al, 2015;Yang et al, 2017;Klinkhamer et al, 2017). Note that we don't refer to the spatial organization of urban assets such as buildings or impervious areas.…”

Section: Introductionsupporting

confidence: 63%

Paradoxical impact of sprawling intra-Urban Heat Islets: Reducing mean surface temperatures while enhancing local extremes

Shreevastava¹,

Bhalachandran²,

McGrath³

et al. 2019

Preprint

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Cities are at the forefront of climate change impacts and face a growing burden of adaptation to ensuing natural hazards. Extreme heat is a particularly challenging hazard as persistent heatwaves are locally exacerbated by the Urban Heat Island (UHI) effect. As a result, there is an increasing scientific interest in the influence of diverse urban morphologies on UHI. However, as the temperatures within cities are highly spatially heterogeneous, bulk quantification metrics such as UHI Intensity may hamper understanding. Here, we use remotely sensed Land Surface Temperature (LST) data for 78 diverse cities to develop a novel multi-scale framework of quantifying spatial heterogeneity in the Surface UHI. We identify heat clusters emerging within the SUHI using percentile-based thermal thresholds and refer to them collectively as \textit{intra-Urban Heat Islets}. We first develop a Lacunarity based metric ($\Lambda_{score}$) to quantify the spatial organization of heat islets at various degrees of sprawl and densification. Using probabilistic models, we condense the size, spacing, and intensity information about heterogeneous clusters into distributions that can be described using single scaling exponents. This allows for a seamless comparison of the heat islet characteristics across cities at varying spatial scales. From the size distribution analysis, we observe the emergence of two distinct classes wherein the dense cities (positive $\Lambda_{score}$) follow a Pareto size distribution, whereas the sprawling cities (negative $\Lambda_{score}$) show an exponential tempering of Pareto tail. This indicates a significantly reduced probability of encountering large heat islets for sprawling cities. Contrastingly, however, Heat Islet Intensity modeled as exponential distributions reveal that a sprawling configuration is favorable for reducing the mean temperature of a city. However, for the same mean SUHI intensity, it also results in higher local thermal extremes. This poses a paradox for urban designers in adopting expansion versus densification as a growth trajectory to mitigate the UHI.

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Section: Introductionsupporting

confidence: 63%

Paradoxical impact of sprawling intra-Urban Heat Islets: Reducing mean surface temperatures while enhancing local extremes

Shreevastava¹,

Bhalachandran²,

McGrath³

et al. 2019

Preprint

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“…In rivers, such pathways are generally determined based on the Horton-Strahler Order, a numerical measure of the networks branching complexity (Strahler 1957). Several studies have applied this ordering scheme in real and virtual sewer systems (Cantone and Schmidt 2011a; Cantone and Schmidt 2011b; Sitzenfrei et al 2013;Yang et al 2017). However, this measure was developed for branching networks (rivers), where only one main flow path exists.…”

Section: Wastewater Collectionmentioning

confidence: 99%

“…drinking water supply and drainage systems, have been however limited, due to lack of data or difficulty of accessing information. In the case of water supply networks, studies have focused on the usage of metrics derived from complex network analysis for the assessment of topological robustness and vulnerability (Yazdani and Jeffrey 2012;Agathokleous et al 2017;Hwang and Lansey 2017;Zeng and Li 2017;Krueger et al 2017;Yang et al 2017;Nazempour et al 2018;Ulusoy et al 2018;Zischg et al 2018). On the other hand, studies related to graphtheory based analysis of Urban Drainage Networks (UDNs) have focused mainly on the evolution and topological characteristics of both virtual (Ghosh et al 2006;Möderl et al 2009;Urich et al 2010) and real sewer systems (Zischg et al 2017;Krueger et al 2017), and on the application of graph-theory based methodologies for determining critical elements in the network (e.g.…”

Section: Introductionmentioning

confidence: 99%

Centrality and shortest path length measures for the functional analysis of urban drainage networks

et al. 2020

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The objective of this research is to evaluate whether complex dynamics of urban drainage networks (UDNs) can be expressed in terms of their structure, i.e. topological characteristics. The present study focuses on the application of topological measures for describing the transport and collection functions of UDNs, using eight subnetworks of the Dresden sewer network as study cases. All UDNs are considered as weighted directed graphs, where edge weights correspond to structural and hydraulic pipe characteristics which affect flow. Transport functions are evaluated in terms of travel time distributions (TTDs), under the hypothesis that frequency distributions of Single Destination Shortest Paths (SDSP) of nodes to the outlet had similar shapes than TTDs. Assessment of this hypothesis is done based on two-sample Kolmogorov-Smirnov tests and comparisons of statistical moments. Collection analysis, i.e. determination of flow paths, is done based on two approaches: (1) using Edge Betweenness Centrality (EBC), and (2) based on the number of SDSP going through an edge connecting a node to the outlet, referred as Paths. Hydrodynamic simulation results are used to validate the outcomes of graph analysis with actual flow behaviors. Results indicate that given an appropriate edge weighting factor, in this case Residence Time, SDSP has the potential to be used as an indicator for flow transport in UDNs. Moreover, both EBC and Paths values were highly correlated to average flows. The first approach, however, proved to be inadequate for estimating flows near the outlet but appropriate for identifying different paths in meshed systems, while the second approach lead to better results in branched networks. Further studies regarding the influence of UDNs layout are needed.

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“…Conceptualizing engineered urban drainage networks as analogs of river networks has improved our understanding of the hydrologic responses of urban areas discharging storm flow and wastewater to rivers (Seo & Schmidt, , ; Yang et al, ). Alterations to hydrological, chemical, and ecological status of receiving rivers and increasing risks to public health are all interconnected manifestations of diverse anthropogenic pressures in urbanized river basins.…”

Section: Introductionmentioning

confidence: 99%

“…Motivated by previous findings for Horton scaling relationships of human‐related variables (Fang et al, ; Miyamoto et al, ), we investigated whether POP distributions in German urbanized basins follow globally consistent patterns of human settlements (Fang et al, ). Knowing that sanitary sewer networks exhibit self‐similar topology like river networks (Yang et al, ), we hypothesized that total PE, the aggregation of POP over multiple sanitary sewer networks, also involves scale‐invariance over H‐S orders. Spatial distribution of WWTPs by H‐S orders reflects not only the total PE‐size distribution over H‐S orders but also the aggregation of PE for multiple WWTPs discharging to a given H‐S order.…”

Section: Introductionmentioning

confidence: 99%

Spatial Organization of Human Population and Wastewater Treatment Plants in Urbanized River Basins

Yang

Büttner

Jawitz

et al. 2019

Water Resources Research

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Discharge from multiple wastewater treatment plants (WWTPs) distributed in urbanized river basins contributes to impairments of river water‐quality and aquatic ecosystem integrity, with size and location of WWTPs determined by population distribution within a river basin. Here we used geo‐referenced data for WWTPs in Germany to investigate the spatial organization of three attributes of interest in this study: population, population equivalents (the aggregated population served by each WWTP), and the number/sizes of WWTPs. To this end, we selected as case studies three large urbanized river basins (Weser, Elbe, and Rhine), home to about 70% of the population in Germany. We employed fractal river networks as structural platforms to examine the spatial patterns from two perspectives: spatial hierarchy (stream order) and patterns along longitudinal flow paths (width function). Moreover, we proposed three dimensionless scaling indices to quantify (1) human settlement preferences by stream order, (2) non‐sanitary flow contribution to total wastewater treated at WWTPs, and (3) degree of centralization in WWTPs locations. Across the three river basins, we found scale‐invariant distributions for each of the three attributes with stream order, quantified using extended Horton scaling ratios. We found a weak downstream clustering of population in the three basins. Variations in population equivalent clustering among different class‐sizes of WWTPs reflected the size, number, and locations of urban agglomerations in these river basins. We discussed the applicability of this approach to other large urbanized basins to analyze spatial organization of population and WWTPs.

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Functional Topology of Evolving Urban Drainage Networks

Cited by 36 publications

References 53 publications

Paradoxical impact of sprawling intra-Urban Heat Islets: Reducing mean surface temperatures while enhancing local extremes

Paradoxical impact of sprawling intra-Urban Heat Islets: Reducing mean surface temperatures while enhancing local extremes

Centrality and shortest path length measures for the functional analysis of urban drainage networks

Spatial Organization of Human Population and Wastewater Treatment Plants in Urbanized River Basins

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