Description
In the middle of the 20th century in the United States, transportation and infrastructure development became a priority on the national agenda, instigating the development of mathematical models that would predict transportation network performance. Approximately 40 years later, transportation planning models again became a national priority, this time instigating the development of highly disaggregate activity-based traffic models called microsimulations. These models predict the travel on a network at the level of the individual decision-maker, but do so with a large computational complexity and processing time requirement. The vast resources and steep learning curve required to integrate microsimulation models into the general transportation plan have deterred planning agencies from incorporating these tools. By researching the stochastic variability in the results of a microsimulation model with varying random number seeds, this paper evaluates the number of simulation trials necessary, and therefore the computational effort, for a planning agency to reach stable model outcomes. The microsimulation tool used to complete this research is the Transportation Analysis and Simulation System (TRANSIMS). The requirements for initiating a TRANSIMS simulation are described in the paper. Two analysis corridors are chosen in the Metropolitan Phoenix Area, and the roadway performance characteristics volume, vehicle-miles of travel, and vehicle-hours of travel are examined in each corridor under both congested and uncongested conditions. Both congested and uncongested simulations are completed in twenty trials, each with a unique random number seed. Performance measures are averaged for each trial, providing a distribution of average performance measures with which to test the stability of the system. The results of this research show that the variability in outcomes increases with increasing congestion. Although twenty trials are sufficient to achieve stable solutions for the uncongested state, convergence in the congested state is not achieved. These results indicate that a highly congested urban environment requires more than twenty simulation runs for each tested scenario before reaching a solution that can be assumed to be stable. The computational effort needed for this type of analysis is something that transportation planning agencies should take into consideration before beginning a traffic microsimulation program.
Details
Title
- An assessment of stochastic variability and convergence characteristics in travel microsimulation models
Contributors
- Ziems, Sarah Elia (Author)
- Pendyala, Ram M. (Thesis advisor)
- Ahn, Soyoung (Committee member)
- Kaloush, Kamil (Committee member)
- Arizona State University (Publisher)
Date Created
The date the item was original created (prior to any relationship with the ASU Digital Repositories.)
2010
Subjects
- Civil Engineering
- Model Convergence
- Model Variability
- Probabilistic Choice
- Random Number
- TRANSIMS
- Transportation Model
- Statistical matching
- Urban transportation--Arizona--Phoenix Metropolitan Area--Planning--Mathematical models.
- Urban transportation
- City traffic--Arizona--Phoenix Metropolitan Area--Planning--Mathematical models.
- City traffic
Resource Type
Collections this item is in
Note
- thesisPartial requirement for: M.S., Arizona State University, 2010
- bibliographyIncludes bibliographical references (p. 67-69)
- Field of study: Civil engineering
Citation and reuse
Statement of Responsibility
by Sarah Elia Ziems