Overcoming the Last-Mile Problem with Transportation and Land-Use Improvements: An Agent-Based Approach
Authored by Moira L Zellner, Dean Massey, Yoram Shiftan, Jonathan Levine, Maria Josefa Arquero
Date Published: 2016
DOI: 10.14257/ijt.2016.4.1.01
Sponsors:
Federal Highway Administration
USA
Platforms:
NetLogo
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Transit in the United States often suffers from the problem of inability
to deliver travelers all the way from their point of origin to their
destination. This ``last-mile{''} problem is thought to deter transit
use among riders with auto access, even when high-quality transit
service is provided for the majority of the trip distance. This study
explores how transportation improvements, including automated driverless
shuttles between origins of trips and nearby transit stations, and
physical improvements enhancing pedestrians' and cyclists' commute might
help overcome the last-mile problem particularly as they interact with
policy shifts including changing in parking and fuel costs. To conduct
this study, we developed an agent-based model representing the commuters
and their preferences for different aspects of transportation
disutility, namely cost, time and safety. Commuters in the model assess
their transportation options in light of their preferences, the
characteristics of their environment, and the various modes available to
them. The model is calibrated with data from four Chicago neighborhoods, representing four different combinations of land-use patterns and
household income. Simulations suggest significant potential for the
combined shuttles and urban design improvements to shift downtown
commuters to non-automotive modes (between 12 and 21 percentage point
reduction in driving in three out of four neighborhoods). Less dense
neighborhoods were more sensitive to higher parking costs, streetscape
improvements and shuttle service than the denser and more
pedestrian-oriented neighborhoods. Distance from the station encouraged
driving, but the presence of shuttles encouraged shifts towards transit.
Streetscape improvements tended to support transit use closer to train
stations. In addition to anticipating a range of likely mode choice
outcomes, the agent-based modeling approach facilitates exploration of
the mechanism underlying travelers' behavior. Rather than modeling
through data fitting, our approach involved formulating theory of
behavior first, using data to parameterize the conceptual model, and
running simulations to see how the outputs would match observations.
When discrepancies arose, we advanced the theory and reformulated the
conceptual model to explain them. In this way, we found that a dense bus
service shuttling travelers towards the commuter train station with
express service downtown was critical in encouraging transit use, and
extensive bus coverage throughout another neighborhood encouraged bus
use to access downtown. Bike penalties representing various difficulties
inherent to this mode (e.g., lack of physical fitness, the need for
showering facilities at the destination, etc.) needed to be adjusted to
higher values than those typically found in the literature, suggesting
greater barriers to biking in this metropolitan area. Finally, we had
hypothesized that pedestrian and biker presence would represent an
important feedback promoting shifts away from driving, but this was not
the case. Further in-depth empirical research is needed to improve our
conceptual models of this feedback, and to understand how policy can
leverage it to encourage greater transit, pedestrian and bicycle use.
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