Abstract
Providing long-term data about the evolution of railway networks in Europe may help us understand how European Union (EU) member states behave in the long-term, and how they can comply with present EU recommendations. This paper proposes a methodology for collecting data about railway stations, at the maximal extent of the French railway network, a century ago.The expected outcome is a geocoded dataset of French railway stations (gares), which: (a) links gares to each other, (b) links gares with French communes, the basic administrative level for statistical information. Present stations are well documented in public data, but thousands of past stations are sparsely recorded, not geocoded, and often ignored, except in volunteer geographic information (VGI), either collaboratively through Wikipedia or individually. VGI is very valuable in keeping track of that heritage, and remote sensing, including aerial photography is often the last chance to obtain precise locations. The approach is a series of steps: (1) meta-analysis of the public datasets, (2) three-steps fusion: measure-decision-combination, between public datasets, (3) computer-assisted geocoding for ‘gares’ where fusion fails, (4) integration of additional gares gathered from VGI, (5) automated quality control, indicating where quality is questionable. These five families of methods, form a comprehensive computer-assisted reconstruction process (CARP), which constitutes the core of this paper. The outcome is a reliable dataset—in geojson format under open license—encompassing (by January 2021) more than 10,700 items linked to about 7500 of the 35,500 communes of France: that is 60% more than recorded before. This work demonstrates: (a) it is possible to reconstruct transport data from the past, at a national scale; (b) the value of remote sensing and of VGI is considerable in completing public sources from an historical perspective; (c) data quality can be monitored all along the process and (d) the geocoded outcome is ready for a large variety of further studies with statistical data (demography, density, space coverage, CO2 simulation, environmental policies, etc.).
Highlights
Transport infrastructure for people and goods is as old as urban civilizations, e.g., Via Appia, Aemilia, Aurelia, etc. have helped in structuring the European landscape for centuries
The developed routines combined in aover computer-assisted reconstruction the dataset of French gares, the 1920–2020 time span; procedure; 3
The Computer-Assisted Reconstruction Procedure –computer-assisted reconstruction procedure (CARP)- data result from the fusion (Section 4.2.1) and from the volunteer geographic information (VGI) integration (Section 4.2.2)
Summary
Transport infrastructure for people and goods is as old as urban civilizations, e.g., Via Appia, Aemilia, Aurelia, etc. have helped in structuring the European landscape for centuries. Have helped in structuring the European landscape for centuries. From 1920 to 2020, the evolution of road and rail networks is a well known element of their competition [1,2,3]. Today climate challenges reignite that century-old debate:for instance the European Union (EU) transportation white paper [4] notes that in 2010 rail yielded million tons of CO2 , versus road: 191 m tons, but regrets “ . Linking railway data with socio-eco-demographic data in historical geographic information systems (GIS), would contribute to understanding long-term trends. This approach has been developed by Siebert [5], and, in Europe by Gregory et al [6], and Morillas-Torné [7].
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