Design a Robust Logistics Network with an Artificial Physarum Swarm Algorithm

Cai, Zhengying; Yang, Yuanyuan; Zhang, Xiangling; Zhou, Yan

doi:10.3390/su142214930

Cited by 8 publications

(10 citation statements)

References 47 publications

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“…The ability or behavior rules of each individual in a heuristic algorithm are very simple, so the realization of heuristic intelligence is relatively convenient and has the characteristics of simplicity. Examples include the genetic algorithm (GA) [5,36], artificial fish swarm algorithm (AFSA) [8], fuzzy logic (FL) [9,32], simulated annealing (SA) [12], particle swarm optimization (PSO) [18,37], deep reinforcement learning (DRL) [19,20,38], ant colony optimization (ACO) [21,39], machine learning (ML) and artificial neural networks (ANNs) [22,38,40], artificial bee colony (ABC) [23,41], grey wolf optimization (GWO) [24], artificial plant community (APC) [42], whale optimization algorithm(WOA) [43], and artificial slime mold (ASM) [13,44,45]. The heuristic algorithms can help us obtain a satisfactory feasible solution in a short time, but the deviation degree between the feasible solution and the optimal solution cannot be predicted.…”

Section: Literature Reviewmentioning

confidence: 99%

“…Constraint 4 in Equation (13) indicates that the transportation volume Q vki of electric vehicle v k on all nodes should not surpass the maximum transportation volume Q vk of electric vehicle v k . Therefore, the maximum amount of cargo carried by an electric vehicle during each mission cannot exceed the vehicle's own carrying capacity limit.…”

Section: Building a Multi-objective Function Of The Elrpmentioning

confidence: 99%

“…Recently, researchers generally believe that the ELRP problem is a more complex task than a traditional location-routing problem (LRP). And the application of the ELRP will become increasingly widespread with the popularity of electric vehicles, such as charging station locations [2,11], battery swapping stations [12], smart cities [6], urban logistics [9,13], home health care [12], waste collection [14], electric trucks [7], electric aircraft [15], and electric buses [16].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

An Artificial Physarum polycephalum Colony for the Electric Location-Routing Problem

Cai,

Wang,

et al. 2023

Sustainability

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Electric vehicles invented for environmental sustainability are prone to adverse impacts on environmental sustainability due to the location and construction of their charging facilities. In this article, an artificial Physarum polycephalum colony is proposed to solve the novel challenging problem. First, the electric location-routing problem is established as a multi-objective network panning model with electric constraints to provide the optimal charging infrastructure layout, electric vehicle maintenance costs, and traffic conditions. The electric facility location problem and vehicle routing problem are integrated by integer programming, which considers the total distance, total time, total cost, total number of electric vehicles, and order fill rate. Second, an artificial Physarum polycephalum colony is introduced to solve the complex electric location-routing problem and includes the two basic operations of expansion and contraction. In the expansion operation, the optimal parent individuals will generate more offspring individuals, so as to expand the population size. In the contraction operation, only individuals with high fitness will be selected to survive through a merge sorting algorithm, resulting in a decrease in population size to the initial value. Through the iterative computing of the two main operations, the proposed artificial Physarum polycephalum colony can finally find the optimal solution to the objective function. Third, a benchmark test is designed for the electric location-routing problem by extracting the real road network from Tokyo, and the experimental results prove the effectiveness and applicability of this work.

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Section: Literature Reviewmentioning

confidence: 99%

Section: Building a Multi-objective Function Of The Elrpmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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An Artificial Physarum polycephalum Colony for the Electric Location-Routing Problem

Cai,

Wang,

et al. 2023

Sustainability

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“…Although swarm intelligence algorithms have been proven effective, they have also been complained of being prone to premature local optima. The Physarum polycephalum in nature can stretch out tens of thousands of filamentous hyphae to search for surrounding food [17,18,47]. This inspires us as to whether the swarm intelligence of Physarum polycephalum can be utilized to provide us with a more efficient algorithm for solving image segmentation problems.…”

Section: Related Workmentioning

confidence: 99%

“…Inspired by the intelligent behavior of a natural Physarum polycephalum, which can produce a large number of hyphae to search for food [17,18], a novel artificial Physarum polycephalum colony algorithm (APPCA) is proposed to help us solve the threshold image segmentation. The main contributions of this article are as follows:…”

Section: Introductionmentioning

confidence: 99%

Using an Artificial Physarum polycephalum Colony for Threshold Image Segmentation

Cai,

Li,

Zhang

et al. 2023

Applied Sciences

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Traditional artificial intelligence algorithms are prone to falling into local optima when solving threshold segmentation problems. Here, a novel artificial Physarum polycephalum colony algorithm is proposed to help us solve the difficult problem. First, the algorithm methodology of an artificial Physarum polycephalum colony algorithm is described to search for the optimal solutions by expansion and contraction of a lot of artificial hyphae. Different artificial Physarum polycephalum can learn from each other and produce more hyphae in expansion. In contraction, the artificial Physarum polycephalum colony can select the best hyphae with high fitness through a quick sort algorithm, but the other hyphae with low fitness will be absorbed and disappear. Second, a fitness function is modeled based on Kapur’s entropy for the proposed artificial Physarum polycephalum colony algorithm to search for optimal threshold segmentation solutions. Third, a series of benchmark experiments are implemented to test the proposed artificial Physarum polycephalum colony algorithm, and some state-of-the-art approaches are employed for comparison. The experimental results verified that the proposed algorithm can obtain better accuracy and convergence speed, and is not easier to fall into the local optimal solution too early.

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Frontiers and trends of supply chain optimization in the age of industry 4.0: an operations research perspective

Xu,

Elomri,

Baldacci

et al. 2024

Ann Oper Res

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Industrial 4.0 (I4.0) is believed to revolutionize supply chain (SC) management and the articles in this domain have experienced remarkable increments in recent years. However, the existing insights are scattered over different sub-topics and most of the existing review papers have ignored the underground decision-making process using OR methods. This paper aims to depict the current state of the art of the articles on SC optimization in I4.0 and identify the frontiers and limitations as well as the promising research avenue in this arena. In this study, the systematic literature review methodology combined with the content analysis is adopted to survey the literature between 2013 and 2022. It contributes to the literature by identifying the four OR innovations to typify the recent advances in SC optimization: new modeling conditions, new inputs, new decisions, and new algorithms. Furthermore, we recommend four promising research avenues in this interplay: (1) incorporating new decisions relevant to data-enabled SC decisions, (2) developing data-enabled modeling approaches, (3) preprocessing parameters, and (4) developing data-enabled algorithms. Scholars can take this investigation as a means to ignite collaborative research that tackles the emerging problems in business, whereas practitioners can glean a better understanding of how to employ their OR experts to support digital SC decision-making.

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Design a Robust Logistics Network with an Artificial Physarum Swarm Algorithm

Cited by 8 publications

References 47 publications

An Artificial Physarum polycephalum Colony for the Electric Location-Routing Problem

An Artificial Physarum polycephalum Colony for the Electric Location-Routing Problem

Using an Artificial Physarum polycephalum Colony for Threshold Image Segmentation

Frontiers and trends of supply chain optimization in the age of industry 4.0: an operations research perspective

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