Abstract
In urban planning and transportation management, the centrality characteristics of urban streets are vital measures to consider. Centrality can help in understanding the structural properties of dense traffic networks that affect both human life and activity in cities. Many cities classify urban streets to provide stakeholders with a group of street guidelines for possible new rehabilitation such as sidewalks, curbs, and setbacks. Transportation research always considers street networks as a connection between different urban areas. The street functionality classification defines the role of each element of the urban street network (USN). Some potential factors such as land use mix, accessible service, design goal, and administrators’ policies can affect the movement pattern of urban travelers. In this study, nine centrality measures are used to classify the urban roads in four cities evaluating the structural importance of street segments. In our work, a Stacked Denoising Autoencoder (SDAE) predicts a street’s functionality, then logistic regression is used as a classifier. Our proposed classifier can differentiate between four different classes adopted from the U.S. Department of Transportation (USDT): principal arterial road, minor arterial road, collector road, and local road. The SDAE-based model showed that regular grid configurations with repeated patterns are more influential in forming the functionality of road networks compared to those with less regularity in their spatial structure.
Highlights
Urban commutes using automobiles are important daily tasks for most city dwellers
The importance of each centrality measure is considered based on the random forest technique, the impacts of street network regularity on Street Functional Classification (SFC) based on mixing ratio are discussed
The streets for each city are grouped into four classes based on the functionalityL Principal Arterial road (PAr), Minor Arterial road (MAr), Collector road (Cr), and Local road (Lr)
Summary
Urban commutes using automobiles are important daily tasks for most city dwellers. The urban streets system is a vital network that connects places and people within and across urban areas. The urban street system can be effectively modeled as a network using graph theory, and the commutes become network-constrained movements [1] with each section of the network responsible to move traffic towards the destination. Having information about the elements of the network with particular objectives is very important for planners and engineers. These objectives range from long-distance traveling to serving neighborhood travel to nearby shopping centers. The effect of the spatial configuration of the street network on traffic flow has been studied by several researchers [2,3,4,5,6,7]. In our work, the spatial configuration of the network is used to classify the functionality of individual streets
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