A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Comparison of Neural Networks and Gravity Models in Trip Distribution
Abstract: Transportation engineers are commonly faced with the question of how to extract information from expensive and scarce field data. Modeling the distribution of trips between zones is complex and dependent on the quality and availability of field data. This research explores the performance of neural networks in trip distribution modeling and compares the results with commonly used doubly constrained gravity models. The approach differs from other research in several respects; the study is based on both synthetic data, varying in complexity, as well as real‐world data. Furthermore, neural networks and gravity models are calibrated using different percentages of hold out data. Extensive statistical analyses are conducted to obtain necessary sample sizes for significant results. The results show that neural networks outperform gravity models when data are scarce in both synthesized as well as real‐world cases. Sample size for statistically significant results is forty times lower for neural networks.
Comparison of Neural Networks and Gravity Models in Trip Distribution
Abstract: Transportation engineers are commonly faced with the question of how to extract information from expensive and scarce field data. Modeling the distribution of trips between zones is complex and dependent on the quality and availability of field data. This research explores the performance of neural networks in trip distribution modeling and compares the results with commonly used doubly constrained gravity models. The approach differs from other research in several respects; the study is based on both synthetic data, varying in complexity, as well as real‐world data. Furthermore, neural networks and gravity models are calibrated using different percentages of hold out data. Extensive statistical analyses are conducted to obtain necessary sample sizes for significant results. The results show that neural networks outperform gravity models when data are scarce in both synthesized as well as real‐world cases. Sample size for statistically significant results is forty times lower for neural networks.
Comparison of Neural Networks and Gravity Models in Trip Distribution
Tillema, Frans (author) / Van Zuilekom, Kasper M. (author) / Van Maarseveen, Martin F. A. M. (author)
Computer‐Aided Civil and Infrastructure Engineering ; 21 ; 104-119
2006-02-01
16 pages
Article (Journal)
Electronic Resource
English
Comparison of Neural Networks and Gravity Models in Trip Distribution
| Online Contents | 2006
Systematic comparison of trip distribution laws and models
| Elsevier | 2016
Systematic comparison of trip distribution laws and models
| Elsevier | 2015
Systematic comparison of trip distribution laws and models
| Online Contents | 2016