Road centre line simplification principles for angular segment analysis

Angular segment analysis is one of the most fundamental analyses in space syntax practice that helps understand movement, land-use and other socio-economic patterns. It was initially applied in axial segment maps and later was used in road centre line maps as an attempt to overcome the 'segment problem' (Turner, 2005). Furthermore, the growing need to examine large urban systems has led to the wide use of road centre line maps instead of the previously hand-drawn axial maps. However, this transition to such datasets has lacked systematic studies on what is required to convert a road centre line map into a segment map, in order to produce reliable results of the angular segment analysis. To date, no consensual methodology has been developed within the space syntax community. This paper attempts to clarify what a road centre line segment represents spatially and suggests principles and rules to simplify a road centre line map to a segment map. Based on previous experience, the simplification mostly relies on the following two principles: reducing the number of nodes in the dual graph representation of a street network; optimising the angular change between adjacent nodes of the dual graph when space allows it. In addition to the above general principles, we discuss rules for special and complex cases, e.g. roundabouts, underpasses, bridges etc. To evaluate these rules and principles comparisons are carried out between traditional axial and RCL unsimplified and simplified segment maps, to develop a good understanding of how changes in dual graph representation of a street network can affect space syntax measure of 'choice'. Correlations of angular segment choice values are performed in order to evaluate which simplification technique can approximate better the axial representation of actual human activity. The results show that using a raw road centre line data set raises several inconsistencies in the analysis results, and the progressive application of the different simplification techniques brings these results closer to those of a traditional axial segment map, and thus to a better representation of socio-economic activity. The purpose of simplification is to minimise inconsistencies to ensure maximum accuracy in the results of angular segment analysis.

[1]  Bill Hillier,et al.  Compositional and urban form effects on residential property value patterns in Greater London , 2013 .

[2]  Nick Dalton,et al.  Fractional Configurational Analysis And a solution to the Manhattan problem , 2001 .

[3]  Mordechai Haklay,et al.  The spatial signature of suburban town centres , 2010 .

[4]  Jorge Gil,et al.  Street network analysis “edge effects”: Examining the sensitivity of centrality measures to boundary conditions , 2017 .

[5]  Tao Yang,et al.  Normalising least angle choice in Depthmap - and how it opens up new perspectives on the global and local analysis of city space , 2012 .

[6]  Bin Jiang,et al.  AxialGen: A Research Prototype for Automatically Generating the Axial Map , 2009, ArXiv.

[7]  Alasdair Turner,et al.  From Axial to Road-Centre Lines: A New Representation for Space Syntax and a New Model of Route Choice for Transport Network Analysis , 2007 .

[8]  Bill Hillier,et al.  Compositional and urban form effects on centres in Greater London , 2012 .

[9]  Nick Dalton,et al.  Extending weighted angular integration analysis to the description of GIS road-centerline data for large scale urban analysis , 2003 .

[10]  Bill Hillier,et al.  The social logic of space: Buildings and their genotypes , 1984 .

[11]  A Turner,et al.  Angular analysis: a method for the quantification of space , 2000 .

[12]  A Turner Could a road-centre line be an axial line in disguise? , 2005 .

[13]  Claire Ellul,et al.  From the axial line to the walked line: Evaluating the utility of commercial and user-generated street network datasets in space syntax analysis , 2012 .

[14]  Bill Hillier,et al.  Network and Psychological Effects in Urban Movement , 2005, COSIT.