Fuzzy-GSA Based Control Approach for Developing Adaptive Cruise Control
Subject Areas : Mechanical Engineering
1 - Sama technical and vocational training college, Islamic Azad University, Kazerun Branch, Kazerun, Iran
Keywords:
Abstract :
[1] Weisswange, T. H., Bolder, B., Fritsch, J., Hasler, S., and Goerick, C., “An Integrated ADAS for Assessing Risky Situations in Urban Driving”, IEEE Intelligent Vehicles Symposium IV, 2013, pp. 292- 297.
[2] Luo, X., Du, W., and Zhang, J., “Safety Benefits of Motorized Seat Belt as a Component in ADAS in Front-End Collisions”, IEEE 17th International Conference on Intelligent Transportation Systems (ITSC), 2014, pp. 661-666.
[3] Gruyer, D., Pechberti, S., and Glaser, S., “Development of Full Speed Range ACC with SiVIC, a Virtual Platformfor ADAS Prototyping, Test and Evaluation”, IEEE Intelligent Vehicles Symposium Workshops IV, 2013, pp. 93-98.
[4] García, F., Escalera, A., and Armingol, J. M., “Enhanced Obstacle Detection Based on Data Fusion for ADAS Applications”, 16th International IEEE Annual Conference on Intelligent Transportation Systems, 2013, pp. 1370-1375
[5] Liu, S., Huang, Y., and Zhang, R., “Obstacle Recognition for ADAS Using Stereovision and Snake Models”, IEEE 17th International Conference on Intelligent Transportation Systems (ITSC), 2014, pp. 99-104.
[6] Dixit, R. S., Gandhe, S. T., “Pedestrian Detection System for ADAS Using Friendly ARM”, International Conference on Energy Systems and Applications (ICESA), 2015, pp. 557-560.
[7] Devapriya, W., Kennedy, C. N., and Srihari T., “Advance Driver Assistance System (ADAS) Speed Bump Detection”, IEEE International Conference on Computational Intelligence and Computing Research, 2015, pp. 1-6.
[8] Guo, C., Meguro J., Kojima, Y., and Naito T., “A Multimodal ADAS System for Unmarked Urban Scenarios Based on Road Context Understanding”, IEEE Transactions on Intelligent Transportation Systems, 2014, pp. 1-15.
[9] Crow, J., Parker, R., “Automatic Headway Control - an Automatic Vehicle Spacing System”, International Society of Automotive Engineering (SAE), 1970, pp. 1-12.
[10] Geamanu, M. S., Cela, A., LeSolliec, G., Mounier, H., and Niculescu, S., “Maximum Friction Estimation and Longitudinal Control for a Full In-Wheel Electric Motor Vehicle”, IEEE 12th Control, Automation and Systems, International Conference (ICCAS), 2012.
[11] Mammar, S., Oufroukh, N. A., Nouveli`ere, L., and Gruyer, D., “Integrated Automated Vehicle String Longitudinal Control”, IEEE Intelligent Vehicles Symposium IV, 2013, pp. 803-808.
[12] Takasaki, G. M., and Fenton R. E., “On Vehicle Longitudinal Dynamics Identification and Control”, IEEE 26th Vehicular Technology Conference, 1976, pp. 16-20.
[13] Lian, Y., Zhao, Y., Hu, L., and Tian, Y., “Longitudinal Collision Avoidance Control of Electric Vehicles Based on a New Safety Distance Model and Constrained Regenerative Braking Strength Continuity Braking Force Distribution Strategy”, IEEE Transactions on Vehicular Technology, 2015, pp. 1-17.
[14] Corno, M., Lucchetti, A., Boniolo, I., and Savaresi, S. M., “Coordinated Lateral and Longitudinal Vehicle Dynamics Control of a Scale RC Vehicle”, American Control Conference, 2015, pp. 1433-1438.
[15] Tai, M., Tomizuka, M., “Robust Longitudinal Velocity Tracking of Vehicles Using Traction and Brake Control”, IEEE Advanced Motion Control Workshop, 2000, pp. 305-310.
[16] Muller, R., Nocker, G., “Intelligent Cruise Control with Fuzzy Logic”, Symposium Proceedings of the Intelligent Vehicles, 1992, pp. 173-178.
[17] Zlocki, A., Themann, P., “Methodology for Quantification of Fuel Reduction Potential for Adaptive Cruise Control Relevant Driving Strategies”, Intelligent Transport Systems (IET), Vol. 7, Issue 1, 2014, pp. 68-75.
[18] Zhang, J., Ioannou, P. A., “Longitudinal Control of Heavy Trucks in Mixed Traffic: Environmental and Fuel Economy Considerations”, IEEE Transactions on Intelligent Transportation Systems, Vol. 7, No. 1. 2006, pp. 92-104.
[19] Flehmig, F., Sardari, A., Fischer, U., and Wagner, A., “Energy Optimal Adaptive Cruise Control During Following of Other Vehicles”, IEEE Intelligent Vehicles Symposium IV, 2015, pp. 724-729.
[20] Naranjo, J. E., González, C., Reviejo, J., García, R., and Pedro, “Adaptive Fuzzy Control for Inter-Vehicle Gap”, IEEE transactions on Intelligent Transportation System, Vol. 4, No. 3, 2003, pp. 132-142.
[21] Cai, L., Rad, A. B., Chan, W. L., and Ho, M. L., “A Neural-Fuzzy Controller for Intelligent Cruise Control of Vehicle in Highways”, IEEE Intelligent Transportation Systems Proceedings, 2003, pp. 1389-1393.
[22] Liang, B., Lin, W. S., “Vehicular Adaptive Optimal Cruise Control with Multiple Objectives”, IEEE International Conference on Systems, Man and Cybernetics, 2012, pp. 2539-2544.
[23] Su´arez, J. I., Vinagre, B. M., and Chen, Y. Q., “Spatial Path Tracking of an Autonomous Industrial Vehicle Using Fractional Order Controllers”, ICAR 11th Int. Conf. on Advanced Robotics, 2003, pp. 405–410.
[24] Rossetter, E. J., Gerdes, J. C., “Performance Guarantees for Hazard Based Lateral Vehicle Control”, Proc. ASME. Dynamic Systems and Control, 2002, pp. 1-11.
[25] Luo, L., Liu, H., Li, P., and Wang, H., “Model Predictive Control for Adaptive Cruise Control with Multi-Objectives: Comfort, Fuel-Economy, Safety and Car-Following”, Journal of Zhejiang University, Vol. 11, Issue 1, 2010, pp. 191-201.
[26] Ioannou, P., Xu, Z., Eckert, S., Clemons, D., and Sieja, T., “Intelligent Cruise Control: Theory and Experiment”, IEEE 32nd Decision and Control Conference, 1993, pp. 1885-1890.
[27] Higashimata, A., Adachi, K., Hashizume, T., and Tange, S., “Design of a Headway Distance Control System for ACC”, JSAE, Vol. 22, Issue 1, 2001, pp. 15-22.
[28] Zheng, P., McDonald, M., “Manual vs. Adaptive Cruise Control, Can Driver’s Expectation Be Matched”, Transportation Research Part C: Emerging Technologies, Vol. 13, Issues 5–6, 2005, pp. 421–431.
[29] Sathiyan, P., Kumar, S., and Selvakumar, A., “Optimized Fuzzy Controller for Improved Comfort Level During Transition in Cruise and Adaptive Cruise Control Vehicles”, IEEE Transactions on Evolutionary Computation, 2015, pp. 86-91.
[30] Takahashi, H., “Automatic Speed Control Device Using Self-Tuning Fuzzy Logic”, IEEE Workshop on Automotive Applications of Electronics, 1988, pp. 65-71.
[31] Idriz, A. F., “Safe Interaction Between Lateral and Longitudinal Adaptive Cruise Control in Autonomous Vehicles”, Ph.D. Dissertation, Mechanical Engineering Dept., Delft University of Technology, 2015.
[32] Pérez, J., Milanés, V., Godoy, J., Villagrá, J., and Onieva, E., “Cooperative Controllers for Highways Based on Human Experience”, Expert Systems with Applications, Vol. 40, Issue 4, 2013, pp 1024–1033.
[33] Maeda, M., “Fuzzy Drive Expert System for an Automobile”, Information Sciences Applications, Vol. 4, No. 1, 1995, pp. 29-48.
[34] Khayyam, H., Nahavandi, S., and Davis, S., “Adaptive Cruise Control Cook-Ahead System for Energy Management of Vehiclesˮ, Expert Systems with Applications, Vol. 39, No. 3, 2012, pp. 3874-3885.
[35] Higashimata, A., Adachi, K., Hashizume, T., and Tange, S., “Design of a Headway Distance Control System for ACC”, JSAE, Vol. 22, No. 1, 2001, pp. 15-22.
[36] Zadeh, L. A., “Fuzzy Sets”, Journal of information and control, Vol. 8, No. 3, 1965, pp. 338-353.
[37] Mamdani, E. H., “Application of Fuzzy Algorithms for Control of Simple Dynamic Plant”, Proceedings of The Institution of Electrical Engineers, Vol. 121, No. 12, 1974, pp. 1585-1588.
[38] Juang, J., Chio, J., “Aircraft Landing Control Lased on Fuzzy Modeling Networks”, IEEE International Conference on Control Applications, 2002, pp. 144-149.
[39] Zaheer, S., Kim, J., “Type-2 Fuzzy Airplane Altitude Control, a Comparative Study”, IEEE International Conference on Fuzzy Systems, 2011, pp. 2370-2376.
[40] Juang, J., Lin, B., and Chin, K., “Automatic Landing Control Using Particle Swarm Optimization”, IEEE International Conference on Mechatronics, 2005, pp. 721-726.
[41] Cheok, D., Shiomi, S., “Combined Heuristic Knowledge and Limited Measurement Based Fuzzy Logic Antiskid Control for Railway Applications”, IEEE Transactions on Man and Cybernetics Vol. 30, No. 4, 2000, pp. 554-568.
[42] Chernov, V., Bogachev, V. A., and Karpenko, E. V., “Rough and Fuzzy Sets Approach for Incident Identification in Railway Infrastructure Management System”, IEEE International Conference on Soft Computing and Measurements (SCM), 2016, pp. 228-230.
[43] Poursamad, A., Montazeri, M., “Design of Genetic-Fuzzy Control Strategy for Parallel Hybrid Electric Vehicles”, Control engineering practice, Vol. 16, No. 7, 2008, pp. 861-873.
[44] Bostanian, M., Barakati, S. M., Najjari B., and Kalhori D. M., “A Genetic-Fuzzy Control Strategy for Parallel Hybrid Electric Vehicle”, International Journal of Automotive Engineering (IJAE) Vol. 3, No. 3, 2013, pp. 482-495.
