A Branch and Bound Method to the Continuous Time Model Elevator System with Full Information

Shen, Zong–Yang; Zhao, Qianchuan

doi:10.9746/jcmsi.1.467

Cited by 4 publications

(3 citation statements)

References 12 publications

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“…One of the authors have tackled to the EOP from 2002, and have published a survey paper in Japanese at 2012 [10]. There are some academic studies [11,12,13,14] which have treated the EOP as optimization problems. Especially, the optimal operation rule for the up-peak traffic pattern was displayed in [14], whereas that rule requires such unavailable information as the arrival rate of passengers.…”

Section: Short Overview On the Literaturementioning

confidence: 99%

“…Especially, the optimal operation rule for the up-peak traffic pattern was displayed in [14], whereas that rule requires such unavailable information as the arrival rate of passengers. Other studies have no guarantee to yield optimal solutions, due to the incomplete formulation [12], the utilization of the receding horizon approach [11], and the utilization of the genetic algorithm [13]. One of the authors made it possible to yield optimal solutions for the deterministic and stochastic EOPs by deploying the integer linear programming [4,16] and the dynamic programming [15], respectively.…”

Section: Short Overview On the Literaturementioning

confidence: 99%

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Proposal and Progress of a Road-map to Bridge Theoretical and Practical Approaches for Elevator Operation Problems

Inamoto

Higami

Kobayashi

2017

International Journal of Smart Computing and Artificial Intelligence

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In this paper, the authors propose a road-map to bridge theoretical and practical approaches in the discipline of the elevator operation problem. The theoretical approach aims to solve static elevator operation problems, here static denotes all information on users of the elevator system is known before scheduling. The practical approach aims to construct rule-bases for realistic situations, where the user's behavior is not known in detail, but known to obey a certain traffic pattern. The authors expect efforts for bridging those approaches to yield a supervised learning of rule-bases by using optimal solutions as teaching data.The proposed road-map is comprised of 5 stages: (1) to obtain an optimal solution for a problem instance of a static elevator operation problem, (2) to construct an identical optimal rule-base from the optimal solution, (3) to construct a similar optimal rule-base which is based on some characteristic functions and effective only for that problem instance, (4) to construct a rule-base which is effective for a set of problem instances, and finally (5) to construct a rule-base which is effective for various problem instances. Computational result display current progress in earlier stages of the road-map.

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Section: Short Overview On the Literaturementioning

confidence: 99%

Section: Short Overview On the Literaturementioning

confidence: 99%

Proposal and Progress of a Road-map to Bridge Theoretical and Practical Approaches for Elevator Operation Problems

Inamoto

Higami

Kobayashi

2017

International Journal of Smart Computing and Artificial Intelligence

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“…To demonstrate the near-optimality of solutions, our method (HNPGA) will be first compared with a trip-based branch and bound (BB) method which can generate optimal solutions [35]. The new door action control method is used in both methods.…”

Section: Examplementioning

confidence: 99%

Optimization of Group Elevator Scheduling With Advance Information

Sun

Zhao

Luh

2010

IEEE Trans. Automat. Sci. Eng.

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Abstract-Group elevator scheduling has received considerable attention due to its importance to transportation efficiency for mid-rise and high-rise buildings. One important trend to improve elevator systems is to collect advance traffic information. Nevertheless, it remains a challenge to develop new scheduling methods which can effectively utilize such information. This paper is to solve the group elevator scheduling problem with advance traffic information. This problem is difficult due to various traffic patterns, complicated car dynamics, and combinatorial explosion of the search space. A two-level formulation is developed with passenger-to-car assignment at the high-level and single car dispatching that is innovatively formulated as passenger-to-trip assignment at the low-level. Detailed car dynamics are embedded in simulation models for performance evaluation. Taking advantage of advance information, a new door action control method is suggested to increase the flexibility of elevators. In view of the hierarchical problem structure, a two-level optimization framework is established. Key problem characteristics are exploited to develop an effective trip-based heuristic for single car dispatching, and a hybrid nested partitions and genetic algorithm method for passenger-to-car assignment which can be extended to solve a generic class of sequential decision problems. Numerical results demonstrate solution quality, computational efficiency, benefit of advance information and the new door action control method, and values of new features in our hybrid method. Q. Note to Practitioners-This

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Single elevator scheduling problem with complete information: An exact model using mixed integer linear programming

Feng

2016

2016 American Control Conference (ACC)

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A Branch and Bound Method to the Continuous Time Model Elevator System with Full Information

Cited by 4 publications

References 12 publications

Proposal and Progress of a Road-map to Bridge Theoretical and Practical Approaches for Elevator Operation Problems

Proposal and Progress of a Road-map to Bridge Theoretical and Practical Approaches for Elevator Operation Problems

Optimization of Group Elevator Scheduling With Advance Information

Single elevator scheduling problem with complete information: An exact model using mixed integer linear programming

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