TY - GEN
T1 - Simulation optimization of car-following models using flexible models
AU - Papathanasopoulou, Vasileia
AU - Antoniou, Constantinos
PY - 2014
Y1 - 2014
N2 - Car following behavior is a key component of microscopic traffic simulation. Numerous models based on traffic flow theory have been developed for decades in order to represent the longitudinal interactions between vehicles as realistically as possible. Nowadays, there is a shift from conventional models to data-driven approaches. Data-driven methods are more flexible and allow the incorporation of additional information to estimation of car-following models. On the other hand, conventional car-following models are founded on traffic flow theory, thus providing better insight into traffic behavior. The integration of datadriven methods in applications of intelligent transportation systems is an attractive perspective. Towards this direction, in this research an existing data-driven approach is further validated using another training dataset. Then, the methodology is modified, extended and enriched so that an improved methodological framework to be suggested for the optimization of car-following models. Machine learning techniques, such as classification, locally weighted regression (loess) and clustering, are innovatively integrated. In this paper, validation of the proposed methods is demonstrated on data from two sources: (i) data collected from a sequence of instrumented vehicles in Naples, Italy, and (ii) data from the NGSIM project. In addition, a conventional car-following model, the Gipps?model, is used as reference in order to monitor and evaluate the effectiveness of the proposed method. Based on the encouraging results, it is suggested that machine learning methods should be further investigated as they could ensure reliability and improvement in data driven estimation of carfollowing models.
AB - Car following behavior is a key component of microscopic traffic simulation. Numerous models based on traffic flow theory have been developed for decades in order to represent the longitudinal interactions between vehicles as realistically as possible. Nowadays, there is a shift from conventional models to data-driven approaches. Data-driven methods are more flexible and allow the incorporation of additional information to estimation of car-following models. On the other hand, conventional car-following models are founded on traffic flow theory, thus providing better insight into traffic behavior. The integration of datadriven methods in applications of intelligent transportation systems is an attractive perspective. Towards this direction, in this research an existing data-driven approach is further validated using another training dataset. Then, the methodology is modified, extended and enriched so that an improved methodological framework to be suggested for the optimization of car-following models. Machine learning techniques, such as classification, locally weighted regression (loess) and clustering, are innovatively integrated. In this paper, validation of the proposed methods is demonstrated on data from two sources: (i) data collected from a sequence of instrumented vehicles in Naples, Italy, and (ii) data from the NGSIM project. In addition, a conventional car-following model, the Gipps?model, is used as reference in order to monitor and evaluate the effectiveness of the proposed method. Based on the encouraging results, it is suggested that machine learning methods should be further investigated as they could ensure reliability and improvement in data driven estimation of carfollowing models.
KW - Car-following models
KW - Classification
KW - Clustering
KW - Data-driven approaches
KW - Gipps' model
KW - Intelligent transportation systems
KW - Locally weighted regression (loess)
KW - Machine learning methods
KW - Speed estimation
UR - http://www.scopus.com/inward/record.url?scp=84911944889&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:84911944889
T3 - OPT-i 2014 - 1st International Conference on Engineering and Applied Sciences Optimization, Proceedings
SP - 2700
EP - 2718
BT - OPT-i 2014 - 1st International Conference on Engineering and Applied Sciences Optimization, Proceedings
A2 - Lagaros, N. D.
A2 - Karlaftis, Matthew G.
A2 - Papadrakakis, M.
PB - National Technical University of Athens
T2 - 1st International Conference on Engineering and Applied Sciences Optimization, OPT-i 2014
Y2 - 4 June 2014 through 6 June 2014
ER -