Abstract
This paper deals with crane scheduling in a block of a container terminal equipped with two crossover cranes. We concentrate on the situation when all requests in this block refer to the seaside. This seaside peak time occurs when a container ship is berthed and has to be served as quickly as possible because berthing time is a major cost driver for both, the shipping company and the port operator. In this case, the two cranes highly interfere. We formulate this problem as a MIP, prove its \(\mathcal {NP}\)-hardness and introduce a lower bound. Further, we provide several heuristic solution procedures based on priority rules. A comparison of all procedures concludes this paper and gives insights on how to solve this problem in practice.
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Asariotis, R., Benamara, H., Hoffmann, J., Premti, A., Sanchez, R., Valentine, V., Wilmsmeier, G., Youssef, F.: Review of maritime transport, 2015. Technical report (2015)
Bierwirth, C., Meisel, F.: A survey of berth allocation and quay crane scheduling problems in container terminals. Eur. J. Oper. Res. 202(3), 615–627 (2010)
Bierwirth, C., Meisel, F.: A follow-up survey of berth allocation and quay crane scheduling problems in container terminals. Eur. J. Oper. Res. 244(3), 675–689 (2015)
Bish, E.K.: A multiple-crane-constrained scheduling problem in a container terminal. Eur. J. Oper. Res. 144(1), 83–107 (2003)
Bish, E.K., Chen, F.Y., Leong, Y.T., Nelson, B.L., Ng, J.W.C., Simchi-Levy, D.: Dispatching vehicles in a mega container terminal. OR Spectr. 27, 491–506 (2005)
Bish, E.K., Leong, T.-Y., Li, C.-L., Ng, J.W., Simchi-Levi, D.: Analysis of a new vehicle scheduling and location problem. Nav. Res. Logist. (NRL) 48(5), 363–385 (2001)
Boysen, N., Briskorn, D., Meisel, F.: A generalized classification scheme for crane scheduling with interference. Eur. J. Oper. Res. 258(1), 343–357 (2017)
Briskorn, D., Angeloudis, P.: Scheduling co-operating stacking cranes with predetermined container sequences. Discrete Appl. Math. 201, 70–85 (2015)
Briskorn, D., Jaehn, F., Wiehl, A.: A test suite for scheduling algorithms for cranes in transshipment terminals (Submitted) (2017)
Briskorn, D., Zey, L.: Scheduling triple crossover-cranes with predetermined container sequences (Submitted) (2017)
Cao, Z., Lee, D.-H., Meng, Q.: Deployment strategies of double-rail-mounted gantry crane systems for loading outbound containers in container terminals. Int. J. Prod. Econ. 115, 221–228 (2008)
Cheung, R.K., Li, C.-L., Lin, W.: Interblock crane deployment in container terminals. Transp. Sci. 36(1), 79–93 (2002)
Dorndorf, U., Schneider, F.: Scheduling automated triple cross-over stacking cranes in a container yard. OR Spectr. 32, 617–632 (2010)
Ehleiter, A., Jaehn, F.: Housekeeping: foresightful container repositioning. Int. J. Prod. Econ. 179, 203–211 (2016)
Garey, M.T., Johnson, D.S.: Computers and Intractability-A Guide to the Theory of NP-Completeness. Freeman&Co, San Francisco (1979)
Gharehgozli, A.H., Laporte, G., Yu, Y., de Koster, R.: Scheduling twin yard cranes in a container block. Transp. Sci. (2014)
Gharehgozli, A.H., Vernooij, F.G., Zaerpour, N.: A simulation study of the performance of twin automated stacking cranes at a seaport container terminal. Eur. J. Oper. Res. 261(1), 108–128 (2017)
Goodchild, A.V., Daganzo, C.F.: Double-cycling strategies for container ships and their effect on ship loading and unloading operations. Transp. Sci. 40(4), 473–483 (2006)
HHLA: Hamburger Hafen und Logistik AG (2014). http://www.hhla.de/
Jaehn, F., Kress, D.: Scheduling cooperative gantry cranes with seaside and landside jobs. Discrete Appl. Math. 242, 53–68 (2018). https://doi.org/10.1016/j.dam.2017.06.015
Kang, J., Oh, M.-S., Ahn, E.Y., Ryu, K.R., Kim, K.H.: Planning for intra-block remarshalling in a container terminal. In: Advances in Applied Artificial Intelligence, pp. 1211–1220. Springer, New York (2006)
Kim, K.H., Kim, K.Y.: An optimal routing algorithm for a transfer crane in port container terminals. Transp. Sci. 33, 17–33 (1999)
Kim, K.Y., Kim, K.H.: Heuristic algorithms for routing yard-side equipment for minimizing loading times in container terminals. Nav. Res. Logist. (NRL) 50(5), 498–514 (2003)
Klaws, J., Stahlbock, R., Voß, S.: Container terminal yard operations—simulation of a side-loaded container block served by triple rail mounted gantry cranes. In: Computational Logistics, pp. 243–255. Springer, New York (2011)
Lee, D.-H., Cao, Z., Meng, Q.: Scheduling of two-transtainer systems for loading outbound containers in port container terminals with simulated annealing algorithm. Int. J. Prod. Econ. 107, 115–124 (2007)
Lee, Y., Hsu, N.-Y.: An optimization model for the container pre-marshalling problem. Comput. Oper. Res. 34(11), 3295–3313 (2007)
Meersmans, P.J.M., Wagelmans, A.P.M.: Effective algorithms for integrated scheduling of handling equipment at automated container terminals. Technical Report EI 2001-19, Econometric Institute, Erasmus University Rotterdam (2001)
Narasimhan, A., Palekar, U.S.: Analysis and algorithms for the transtainer routing problem in container port operations. Transp. Sci. 36, 63–78 (2002)
Ng, W.C.: Crane scheduling in container yards with inter-crane interference. Eur. J. Oper. Res. 164, 64–78 (2005)
Ng, W.C., Mak, K.L.: An effective heuristic for scheduling a yard crane to handle jobs with different ready times. Eng. Optim. 37, 867–877 (2005a)
Ng, W.C., Mak, K.L.: Yard crane scheduling in container terminals. Appl. Math. Model. 29, 263–276 (2005b)
Park, T., Choe, R., Ok, S.M., Ryu, K.R.: Real-time scheduling for twin RMGs in an automated container yard. OR Spectr. 32(3), 593–615 (2010)
Saanen, Y., van Valkengoed, M.: Comparison of three automated stacking alternatives by means of simulation. In: Kuhl, M.E., Steiger, N.M., Armstrong, F. B., Joines, J.A. (eds.) Proceedings of the winter simulation conference, pp. 1567–1576 (2005)
Speer, U., Fischer, K.: Scheduling of different automated yard crane systems at container terminals. Transp. Sci. 51(1), 305–324 (2016)
Speer, U., John, G., Fischer, K.: Scheduling yard cranes considering crane interference. In: Computational Logistics, pp. 321–340. Springer, New York (2011)
Stahlbock, R., Voß, S.: Efficiency considerations for sequencing and scheduling of double-rail-mounted gantry cranes at maritime container terminals. Int. J. Ship. Transp. Logist. 2(1), 95–123 (2010)
Stahlbock, R., Voß, S.: Operations research at container terminals: a literature update. OR Spectr. 30, 1–52 (2008)
Steenken, D., Voß, S., Stahlbock, R.: Container terminal operations and operations research—a classification and literature review. OR Spectr. 26, 3–49 (2004)
Vis, I.F.A.: Survey of research in the design and control of automated guided vehicle systems. Eur. J. Oper. Res. 170, 677–709 (2006)
Vis, I.F.A., Carlo, H.J.: Sequencing two cooperating automated stacking cranes in a container terminal. Transp. Sci. 44, 169–182 (2010)
Zhang, C., Liu, J., Wan, Y.-W., Murty, K.G., Linn, R.J.: Storage space allocation in container terminals. Transp. Res. B Methodol. 37(10), 883–903 (2003)
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This work has been supported by the German Science Foundation (DFG) through the grant “Scheduling mechanisms for rail mounted gantries with respect to crane interdependencies” (JA 2311/2-1).
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Ehleiter, A., Jaehn, F. Scheduling crossover cranes at container terminals during seaside peak times. J Heuristics 24, 899–932 (2018). https://doi.org/10.1007/s10732-018-9380-2
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DOI: https://doi.org/10.1007/s10732-018-9380-2