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  • ارائه ی یک الگوریتم ژنتیک جدید برای حل مسئله ی مسیریابی چند انباره با وسایل نقلیه چند ظرفیتی

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رقم المقالة : 539253 زيارة : 118 الصفحة: 87 - 98

نوع المخطوط: ابحاث

ارائه ی یک الگوریتم ژنتیک جدید برای حل مسئله ی مسیریابی چند انباره با وسایل نقلیه چند ظرفیتی

الموضوعات :

Hossien Afzali 1 ( Researcher at the institute for Trade Student and Research (ITSR) )
Gholam Reza Einy Sarkalleh 2 ( Ph.D. student of industrial management and Researcher at the institute for Trade Student and Research (ITSR) )
Mojtba Khademy Nejad 3 ( M.S in Industrial management )
Elnaz Miandoabchi 4 ( Ph.D. in Industries and Faculty Member of the Institute for Trade Student and Research (ITSR) )

تاريخ الإرسال : 15 الخميس , محرم, 1439 تاريخ التأكيد : 11 الأحد , جمادى الأولى, 1439 تاريخ الإصدار : 23 الإثنين , رجب, 1439

الکلمات المفتاحية: genetic algorithms, الگوریتم های ژنتیک, الگوریتم حریصانه مسیریابی, وسایل نقلیه چند ظرفیتی, چند انباره, Greedy algorithm, Multi-capacity vehicle routing, Multi-storage,

ملخص المقالة :

امروزه مسیریابی وسایل نقلیه یکی از مسائل پرکاربردترین موضوعات و مدل ها در لجستیک و مدیریت زنجیره تامین و به تبع آن در برنامه ریزی حمل و نقل می باشد که تا کنون مقالات و پژوهش های کاربردی و آکادمیک بسیار زیادی در این زمینه انجام شده و به چاپ رسیده است در این مقاله ما به ارائه یک الگوریتم ابتکاری جدید برای حل مساله ی مسیر یابی وسایل نقلیه با ظرفیت های متفاوتی از وسایل نقلیه پرداخته شده است که هدف اساسی این مقاله تخصیص نقاط تقاضا به هر مرکز و تعیین بهترین مسیر بین نقاط تخصیص یافته به هر مرکز و همچنین تعیین بهترین وسیله حمل و نقل برای هر مرکز است و در یک مطالعه موردی این مدل مورد تحلیل و بررسی قرار گرفته است و در ادامه نتایج بدست آمده که توسط الگوریتم جدید استخراج شده است را با الگوریتم های ابتکاری مقایسه گردیده و نتایج بدست آمده نشان می دهد که این الگوریتم توانایی رقابت با الگوریتم های ابتکاری و فراابتکاری های دیگر را نیز خواهد داشت.

المصادر:


  1.  Banos, R., Ortega, J., Gil, C. (1959). Marquez, A.L & de  Toro, F.A., Hybrid meta-heuristic for  multi-objective vehicle routing problems with time  windows ,Computers & Industrial Engineering, 2013 (65): 286-296.
    2.
  2. Baozhen, Yao,  Bin Yu,  Ping Hu, Junjie, Gao. (2015). An improved particle swarm optimization for carton heterogeneous vehicle routing problem with a collection depot Mingheng Zhang.
    3.
  3. Bookbinder, J. H., & Reece, K. E. (1988). Vehicle routing considerations in distribution system design. European Journal of Operational Research, 37, 204–213.
    4.
  4. Bouhafs, L., Hajjam, A., & Koukam, A. (2006). A combination of simulated annealing and ant colony system for the capacitated location-routing problem. Lecture Notes in Computer Science, 4251, 409–416.
    5.
  5. Gerhard Hiermann, Jakob, Puchinger,  Stefan Ropke & Richard F., Hartl. (2016). The Electric Fleet Size and Mix Vehicle Routing Problem with Time Windows and Recharging Stations.
    6.
  6. HoudaDerbel, BassemJarboui, SaïdHanafi, HabibChabchoub. (2012).Genetic algorithm with iterated local search for solving a location-routing problem. Expert Systems with Applications, 39, 2865-2871
    7.
  7. Jacobsen, S. K., & Madsen, O. B. G. (1980). A comparative study of heuristics for a two-level routing-location problem. European Journal of Operational Research, 5,378–387.
    8.
  8. Karp, R. (1972). Reducibility among combinatorial problems.In R. Miller & J. Thatcher (Eds.), Complexity of computer computations. New York, Plenum Press, 85–104.
    9.
  9. Laporte, G., & Nobert, Y. (1981). An exact algorithm for minimizing routing and operating costs in depot location. European Journal of Operational Research, 6(2), 224–226.
    10.
  10. Laporte, G., Nobert, Y., & Pelletier, P. (1983).Hamiltonian location problems. European Journal of Operational Research, 12, 80–87.
    11.
  11. Lin, C. K. Y., Chow, C. K., & Chen, A. (2002). A location-routing-loading problem for bill delivery services. Computers & Industrial Engineering, 43(1–2): 5–25.
    12.
  12. Madsen, O. B. G. (1983). Methods for solving combined two level location routing problems of realistic dimensions. European Journal of Operational Research, 12, 295–301.
    13.
  13. Marinakis, Y., & Marinaki, M. (2008). A particle swarm optimization algorithm with path relinking for the location routing problem. Journal of Mathematical modeling and algorithms, 7, 59–78.
    14.
  14. Min, H., Jayaraman, V., & Srivastava, R. (1998). Combined location-routing problems: A synthesis and future research directions. European Journal of Operational Research, 108(1): 1–15.
    15.
  15. Monirehalsadat Mahmoudi, Xuesong Zhou. (2016). Finding optimal solutions for vehicle routing problem with pickup and delivery services with time windows: A dynamic programming approach based on state–space–time network representations School of Sustainable Engineering and the Built Environment, Arizona State University, Tempe, AZ 85281, USA
    16.
  16. Nagy, G., & Salhi, S. (2007). Location-routing: Issues, models and methods. European Journal of Operational Research, 177, 649–672.
    17.
  17. Prins, C., Prodhon, C., & Wolfler Calvo, R. (2004). Nouveaux algorithms pour le problems de localisationetroutage sous contraintes de capacité. In Proceedings of the MOSIM’, 04, (2): 1115–1122): Lavoisier, Ecole des Mines de Nantes, France.
    18.
  18. Prins, C., Prodhon, C., & Wolfler Calvo, R. (2006). Solving the capacitated location-routing problem by a GRASP complemented by a learning process and a path relinking. 4OR, 4(3): 221–238.
    19.
  19. Prins, C., Prodhon, C., & Wolfler Calvo, R. (2006).A memetic algorithm with population management (MA|PM) for the capacitated location-routing problem. Lecture Notes in Computer Science, 3906, 183–194.
    20.
  20. Prins, C., Prodhon, C., Ruiz, A., Soriano, P., &WolflerCalvo, R. (2007).Solving the capacitated location-routing problem by a cooperative Lagrangean relaxation granular tabu search heuristic. Transportation Science, 41(4), 470–483.
    21.
  21. Salhi, S., & Rand, G. K. (1989). The effect of ignoring routes when locating depots. European Journal of Operational Research, 45, 150–156.
    22.
  22. Tavakkoli-Moghaddam, Reza, Masoudi, Shaqayeq & Eghbali, Hamed. (2016). Solving a New Mathematical Model for a Multi-Objective and Multi-Depot Vehicle Routing Problem by a Non-dominated Sorting Genetic Algorithm,167-175
    23.
  23. Vincent F., Yu, Shih-Wei Lin, Wenyih, Lee, & Ching-Jung Ting. (2009). A simulated annealing heuristic for the capacitated location routing problem. Computers & Industrial Engineering, 58, 288-299.
    24.
  24. Yousefikhoshbakht1, M. & Khorram, E. (2012). Solving the vehicle routing problem by a hybrid meta-heuristic algorithm. Journal of Industrial Engineering International, 8(11): 1-9.
    25.

25. Wu, T. H., Low, C., & Bai, J. W. (2002). Heuristic solutions to multi-depot location-routing problems. Computers & Operations Research, 29(10), 1393–1415.

_||_

  1.  Banos, R., Ortega, J., Gil, C. (1959). Marquez, A.L & de  Toro, F.A., Hybrid meta-heuristic for  multi-objective vehicle routing problems with time  windows ,Computers & Industrial Engineering, 2013 (65): 286-296.
    2.
  2. Baozhen, Yao,  Bin Yu,  Ping Hu, Junjie, Gao. (2015). An improved particle swarm optimization for carton heterogeneous vehicle routing problem with a collection depot Mingheng Zhang.
    3.
  3. Bookbinder, J. H., & Reece, K. E. (1988). Vehicle routing considerations in distribution system design. European Journal of Operational Research, 37, 204–213.
    4.
  4. Bouhafs, L., Hajjam, A., & Koukam, A. (2006). A combination of simulated annealing and ant colony system for the capacitated location-routing problem. Lecture Notes in Computer Science, 4251, 409–416.
    5.
  5. Gerhard Hiermann, Jakob, Puchinger,  Stefan Ropke & Richard F., Hartl. (2016). The Electric Fleet Size and Mix Vehicle Routing Problem with Time Windows and Recharging Stations.
    6.
  6. HoudaDerbel, BassemJarboui, SaïdHanafi, HabibChabchoub. (2012).Genetic algorithm with iterated local search for solving a location-routing problem. Expert Systems with Applications, 39, 2865-2871
    7.
  7. Jacobsen, S. K., & Madsen, O. B. G. (1980). A comparative study of heuristics for a two-level routing-location problem. European Journal of Operational Research, 5,378–387.
    8.
  8. Karp, R. (1972). Reducibility among combinatorial problems.In R. Miller & J. Thatcher (Eds.), Complexity of computer computations. New York, Plenum Press, 85–104.
    9.
  9. Laporte, G., & Nobert, Y. (1981). An exact algorithm for minimizing routing and operating costs in depot location. European Journal of Operational Research, 6(2), 224–226.
    10.
  10. Laporte, G., Nobert, Y., & Pelletier, P. (1983).Hamiltonian location problems. European Journal of Operational Research, 12, 80–87.
    11.
  11. Lin, C. K. Y., Chow, C. K., & Chen, A. (2002). A location-routing-loading problem for bill delivery services. Computers & Industrial Engineering, 43(1–2): 5–25.
    12.
  12. Madsen, O. B. G. (1983). Methods for solving combined two level location routing problems of realistic dimensions. European Journal of Operational Research, 12, 295–301.
    13.
  13. Marinakis, Y., & Marinaki, M. (2008). A particle swarm optimization algorithm with path relinking for the location routing problem. Journal of Mathematical modeling and algorithms, 7, 59–78.
    14.
  14. Min, H., Jayaraman, V., & Srivastava, R. (1998). Combined location-routing problems: A synthesis and future research directions. European Journal of Operational Research, 108(1): 1–15.
    15.
  15. Monirehalsadat Mahmoudi, Xuesong Zhou. (2016). Finding optimal solutions for vehicle routing problem with pickup and delivery services with time windows: A dynamic programming approach based on state–space–time network representations School of Sustainable Engineering and the Built Environment, Arizona State University, Tempe, AZ 85281, USA
    16.
  16. Nagy, G., & Salhi, S. (2007). Location-routing: Issues, models and methods. European Journal of Operational Research, 177, 649–672.
    17.
  17. Prins, C., Prodhon, C., & Wolfler Calvo, R. (2004). Nouveaux algorithms pour le problems de localisationetroutage sous contraintes de capacité. In Proceedings of the MOSIM’, 04, (2): 1115–1122): Lavoisier, Ecole des Mines de Nantes, France.
    18.
  18. Prins, C., Prodhon, C., & Wolfler Calvo, R. (2006). Solving the capacitated location-routing problem by a GRASP complemented by a learning process and a path relinking. 4OR, 4(3): 221–238.
    19.
  19. Prins, C., Prodhon, C., & Wolfler Calvo, R. (2006).A memetic algorithm with population management (MA|PM) for the capacitated location-routing problem. Lecture Notes in Computer Science, 3906, 183–194.
    20.
  20. Prins, C., Prodhon, C., Ruiz, A., Soriano, P., &WolflerCalvo, R. (2007).Solving the capacitated location-routing problem by a cooperative Lagrangean relaxation granular tabu search heuristic. Transportation Science, 41(4), 470–483.
    21.
  21. Salhi, S., & Rand, G. K. (1989). The effect of ignoring routes when locating depots. European Journal of Operational Research, 45, 150–156.
    22.
  22. Tavakkoli-Moghaddam, Reza, Masoudi, Shaqayeq & Eghbali, Hamed. (2016). Solving a New Mathematical Model for a Multi-Objective and Multi-Depot Vehicle Routing Problem by a Non-dominated Sorting Genetic Algorithm,167-175
    23.
  23. Vincent F., Yu, Shih-Wei Lin, Wenyih, Lee, & Ching-Jung Ting. (2009). A simulated annealing heuristic for the capacitated location routing problem. Computers & Industrial Engineering, 58, 288-299.
    24.
  24. Yousefikhoshbakht1, M. & Khorram, E. (2012). Solving the vehicle routing problem by a hybrid meta-heuristic algorithm. Journal of Industrial Engineering International, 8(11): 1-9.
    25.

25. Wu, T. H., Low, C., & Bai, J. W. (2002). Heuristic solutions to multi-depot location-routing problems. Computers & Operations Research, 29(10), 1393–1415.

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