A robust algorithm to solve the signal setting problem considering different traffic assignment approaches

Adacher, L. (2012). A global optimization approach to solve the traffic signal synchronization problem, Procedia-Social and Behavioral Sciences 54: 1270-1277.10.1016/j.sbspro.2012.09.841Search in Google Scholar

Adacher, L. and Cipriani, E. (2010). A surrogate approach for the global optimization of signal settings and traffic assignment problem, 13th International IEEE Conference on Intelligent Transportation Systems (ITSC), Funchal, Portugal, pp. 60-65.Search in Google Scholar

Adacher, L., Cipriani, E. and Gemma, A. (2015). The global optimization of signal settings and traffic assignment combined problem: A comparison between algorithms, Advances in Transportation Studies 36: 35-48.Search in Google Scholar

Adacher, L. and Gemma, A. (2016). An optimizing algorithm to minimize the delay signal setting problem, 3rd International Conference on Mathematics and Computers in Sciences and in Industry (MCSI), Crete, Greece, pp. 197-202.Search in Google Scholar

Allsop, R. and Charlesworth, J. (1977). Traffic in a signal-controlled road network: An example of different signal timings including different routeing, Traffic Engineering & Control 18(5): 262-265.Search in Google Scholar

Cascetta, E., Gallo, M. and Montella, B. (1998). Optimal signal setting on traffic networks with stochastic equilibrium assignment, Proceedings of TRISTAN III, San Juan, Puerto Rico, pp. 17-23.Search in Google Scholar

Ceylan, H. and Bell, M. (2004). Traffic signal timing optimisation based on genetic algorithm approach, including drivers’ routing, Transportation Research B: Methodological 38(4): 329-342.10.1016/S0191-2615(03)00015-8Open DOISearch in Google Scholar

Chang, T. and Sun, G. (2004). Modeling and optimization of an oversaturated signalized network, Transportation Research B: Methodological 38(8): 687-707.10.1016/j.trb.2003.08.002Search in Google Scholar

Chiou, S. (2005). Joint optimization for area traffic control and network flow, Computers & Operations Research 32(11): 2821-2841.10.1016/j.cor.2004.04.006Open DOISearch in Google Scholar

Cohen, S. (1983). Concurrent use of MAXBAND and TRANSYT signal timing programs for arterial signal optimization, Transportation Research Record (906): 81-84.Search in Google Scholar

Cohen, S. and Liu, C. (1986). The bandwidth-constrained TRANSYT signal-optimization program (discussion and closure), Transportation Research Record (1057): 1-7.Search in Google Scholar

Colombaroni, C., Fusco, G., Gemma, A., Demiralp, M., Baykara, N. and Mastorakis, N. (2009). Optimization of traffic signals on urban arteries through a platoon-based simulation model, WSEAS International Conference, Istanbul, Turkey, pp. 450-455.Search in Google Scholar

Fusco, G., Bielli, M., Cipriami, E., Gori, S. and Nigro, M. (2013). Signal settings synchronization and dynamic traffic modelling, European Transport 53, Paper no. 7.Search in Google Scholar

Gokbayrak, K. and Cassandras, C.G. (2002). Generalized surrogate problem methodology for online stochastic discrete optimization, Journal of Optimization Theory and Applications 114(1): 97-132.10.1023/A:1015464105071Search in Google Scholar

Goliya, H. and Jain, N. (2012). Synchronization of traffic signals: “A case study-eastern ring road, Indore”, International Journal of Advanced Technology in Civil Engineering 1(2): 1-7.10.47893/IJATCE.2012.1019Search in Google Scholar

Góngora, P.A. and Rosenblueth, D.A. (2015). A symbolic shortest path algorithm for computing subgame-perfect Nash equilibria, International Journal of Applied Mathematics and Computer Science 25(3): 577-596, DOI: 10.1515/amcs-2015-0043.10.1515/amcs-2015-0043Open DOISearch in Google Scholar

Hadi, M. and Wallace, C. (1993). Algorithm to optimize signal phasing and transportation research record, Transportation Research Record (1421): 104-112.Search in Google Scholar

Khaki, A. and Pour, P. (2014). The impacts of traffic signal timings optimization on reducing vehicle emissions and fuel consumption by aimsun and synchro software’s (Case study: Tehran intersections), International Journal of Civil and Structural Engineering 5(2): 144.Search in Google Scholar

Klaučo, M., Blažek, S. and Kvasnica, M. (2016). An optimal path planning problem for heterogeneous multi-vehicle systems, International Journal of Applied Mathematics and Computer Science 26(2): 297-308, DOI: 10.1515/amcs-2016-0021.10.1515/amcs-2016-0021Open DOISearch in Google Scholar

Köhler, E., Möhring, R., Nökel, K. and Wünsch, G. (2008). Optimization of signalized traffic networks, in H.J. Krebs and W. J¨ager (Eds.), Mathematics-Key Technology for the Future, Springer, Berlin/Heidelberg, pp. 179-188.10.1007/978-3-540-77203-3_13Search in Google Scholar

Malakapalli, M.M. (1993). Enhancements to the PASSER II-90 delay estimation procedures, Transportation Research Record (1421): 94-103.Search in Google Scholar

Nagel, K. and Flötteröd, G. (2012). Agent-based traffic assignment: Going from trips to behavioural travelers, 12th International Conference on Travel Behaviour Research, Jaipur, Rajasthan, India, pp. 261-294.Search in Google Scholar

Park, B., Messer, C. and Urbanik, T. (1999). Traffic signal optimization program for oversaturated conditions: Genetic algorithm approach, Transportation Research Record (1683): 133-142.10.3141/1683-17Open DOISearch in Google Scholar

Robertson, D. (1969). Transyt: A traffic network study tool ministry of transport, RRL Report LR253, Crowthorne, Berkshire.Search in Google Scholar

Smith, M. (2006). Bilevel optimisation of prices and signals in transportation models, in S. Lawphongpanich et al. (Eds.), Mathematical and Computational Models for Congestion Charging, Springer, Boston, MA, pp. 159-199.10.1007/0-387-29645-X_8Search in Google Scholar

Smith, M. (2015). Traffic signal control and route choice: A new assignment and control model which designs signal timings, Transportation Research C: Emerging Technologies 58: 451-473.10.1016/j.trc.2015.02.002Search in Google Scholar

Stevanovic, A., Stevanovic, J., Zhang, K. and Batterman, S. (2009). Optimizing traffic control to reduce fuel consumption and vehicular emissions: Integrated approach with VISSIM, CMEM, and VISGAOST, Transportation Research Record: Journal of the Transportation Research Board (2128): 105-113.10.3141/2128-11Search in Google Scholar

Sun, D., Benekohal, R.F. and Waller, S. (2006). Bi-level programming formulation and heuristic solution approach for dynamic traffic signal optimization, Computer-Aided Civil and Infrastructure Engineering 21(5): 321-333.10.1111/j.1467-8667.2006.00439.xOpen DOISearch in Google Scholar

Szeto, W. and Lo, H. (2006). Dynamic traffic assignment: Properties and extensions, Transportmetrica 2(1): 31-52.10.1080/18128600608685654Open DOISearch in Google Scholar

Teklu, F., Sumalee, A. and Watling, D. (2007). A genetic algorithm approach for optimizing traffic control signals considering routing, Computer-Aided Civil and Infrastructure Engineering 22(1): 31-43.10.1111/j.1467-8667.2006.00468.xOpen DOISearch in Google Scholar

Van den Berg, M., De Schutter, B., Hellendoorn, J. and Hegyi, A. (2008). Influencing route choice in traffic networks: A model predictive control approach based on mixed-integer linear programming, IEEE International Conference on Control Applications, CCA 2008, San Antonio, TX, USA, pp. 299-304.Search in Google Scholar

Xiaojian, H., Jian, L.,Wang, W. and Zhirui, Y. (2015). Research article traffic signal synchronization in the saturated high-density grid road, Computational Intelligence and Neuroscience 2015, Article ID: 532960.10.1155/2015/532960430922025663835Search in Google Scholar