Abstract
Agent-based models for dynamic traffic assignment simulate the behaviour of individual, or group of, agents, and then the simulation outcomes are observed on the scale of the system. As large-scale simulations require substantial computational power and have long run times, most often a sample of the full population and downscaled road capacities are used as simulation inputs, and then the simulation outcomes are scaled up. Using a massively parallelized mobility model on a large-scale test case of the whole of Switzerland, which includes 3.5 million private vehicles and 1.7 million users of public transit, we have systematically quantified, from 6 105 simulations of a weekday, the impacts of scaled input data on simulation outputs. We show, from simulations with population samples ranging from 1% to 100% of the full population and corresponding scaling of the traffic network, that the simulated traffic dynamics are driven primarily by the flow capacity, rather than the spatial properties, of the traffic network. Using a new measure of traffic similarity, that is based on the chi-squared test statistic, it is shown that the dynamics of the vehicular traffic and the occupancy of the public transit are adversely impacted when population samples less than 30% of the full population are used. Moreover, we present evidence that the adverse impact of population sampling is determined mostly by the patterns of the agents’ behaviour rather than by the traffic model.
Highlights
The complexity of modern transportation systems continues to increase in order to efficiently serve the demand from the increasing population in urban areas and to ensure compliance with policies that support the energy transition (Litman 2013; Speranza 2018)
The same behaviour is reported by Llorca and Moeckel (2019) where spatial buffers are scaled with factors larger than the corresponding size of the larger than the standard deviation poofpkuf∗la, ttihoenresfaomreplien.dTichaetisntgantdhaartdsdpeavtiiaaltibounffoefrskl∗aries more sensitive to stochastic fluctuations in the simulated traffic
As the spatial coefficient does not have a strong impact on traffic dynamics, coarser step-sizes can be used in the kl dimension
Summary
The complexity of modern transportation systems continues to increase in order to efficiently serve the demand from the increasing population in urban areas and to ensure compliance with policies that support the energy transition (Litman 2013; Speranza 2018). Emerging technologies such as electric vehicles (EVs) and automated vehicles (AVs) are among the main drivers of the ongoing transformations in the transportation sector (Burns 2013; Hars 2015). There is a trend towards a closer integration of different transportation modes into multi-modal networks with the idea that mobility-as-a-service (Jittrapirom et al 2017) may potentially improve the overall inter-modal interaction of service providers, and especially make public transit more attractive to existing car owners
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