Por favor, use este identificador para citar o enlazar este ítem: http://hdl.handle.net/10259/6982
Título
Spatial analysis of public transportation infrastructure in Santiago, Chile
Publicado en
R-Evolucionando el transporte
Editorial
Universidad de Burgos. Servicio de Publicaciones e Imagen Institucional
Fecha de publicación
2021-07
ISBN
978-84-18465-12-3
DOI
10.36443/10259/6982
Descripción
Trabajo presentado en: R-Evolucionando el transporte, XIV Congreso de Ingeniería del Transporte (CIT 2021), realizado en modalidad online los días 6, 7 y 8 de julio de 2021, organizado por la Universidad de Burgos
Résumé
Santiago, the capital city of Chile, has seven million inhabitants in an area of 850 km2. This
city has a metro network with seven lines extending 140 kilometers and transports
approximately 2.6 million people daily. The bus system has undergone significant
transformations over the last three decades. The most relevant change having been
Transantiago, the public transportation system implemented in 2007 for Santiago, Child,
which combines the use of Metro and buses (BRT). Metropolitan Mobility Network (called
Red) is the latest version of the public transportation plan.
This paper aims to analyze the current subway infrastructure using the continuous
approximation method for Santiago, Chile. We previously proposed a macroscopic
methodology to identify the needs for an adequate level of service in urban mobility and
transportation, and we applied it to Santiago's Metro network. Our work focuses on
functionality and demand distribution. Santiago's demand varies spatially in volume and
extension throughout the city. Using the latest origin-destination survey from 2012, we
deduct the critical components in this current network structure. It is worth mentioning that
the metro design bases its network on a ring-radial structure.
With our macroscopic model applied to Santiago, Chile, we have detected infrastructure
needs in the current transit network. The supply of infrastructure should increase for two
reasons: first, to achieve balanced cost levels between users and the agency and second, to
reduce subway occupations. The optimal model outcomes for Santiago define the optimal
network in which the system requires five rings and ten end-to-end longitudinal lines (20
radial routes), including lower levels of occupation. The obtained results are a good
preliminary solution, considering the subway infrastructure supply could be sub-estimated
in the public transportation plan.
Palabras clave
Planificación del transporte
Planning of transport
Transporte público
Public transport
Materia
Ingeniería civil
Civil engineering
Transportes
Transportation
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