Energy-Efficient Multi-Trip Routing for Municipal Solid Waste Collection by Contribution-Based Adaptive Particle Swarm Optimization

Shen, Xipeng; Pan, Hongli; Ge, Zhongpei; Chen, Wenyan; Song, Liying; Wang, Shuo

doi:10.23919/csms.2023.0008

Cited by 16 publications

(2 citation statements)

References 39 publications

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“…Another strategy is to modify the meta-heuristic algorithm on specific VRP variants to reduce computational complexity. For example, in determining waste collection routes, the adaptive particle swarm optimization method is used, which is equipped with several special strategies for the solution search process [28]. The use of intelligent solution initialization methods and efficient representation can also help reduce processing time and enable exploration of the search space on a larger scale.…”

Section: Scalability In Large Vrp Instancesmentioning

confidence: 99%

Challenges and Opportunities for Applying Meta-Heuristic Methods in Vehicle Routing Problems: A Review

Mahmudy,

Widodo,

Haikal

2024

The 7th Mechanical Engineering, Science and Technology International Conference

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Section: Scalability In Large Vrp Instancesmentioning

confidence: 99%

Challenges and Opportunities for Applying Meta-Heuristic Methods in Vehicle Routing Problems: A Review

Mahmudy,

Widodo,

Haikal

2024

The 7th Mechanical Engineering, Science and Technology International Conference

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“…Owing to the above issues, it is thus critical to design mechanisms for the efficient collection and disposal of waste materials [17][18][19]. Sustainable, eco-friendly, and technologyassisted strategies are needed to develop waste dumping systems.…”

Section: Introductionmentioning

confidence: 99%

Efficient IoT-Assisted Waste Collection for Urban Smart Cities

Khan,

Ali,

Alharbi

et al. 2024

Sensors

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Waste management is one of the many major challenges faced by all urban cities around the world. With the increase in population, the current mechanisms for waste collection and disposal are under strain. The waste management problem is a global challenge that requires a collaborative effort from different stakeholders. Moreover, there is a need to develop technology-based solutions besides engaging the communities and establishing novel policies. While there are several challenges in waste management, the collection of waste using the current infrastructure is among the top challenges. Waste management suffers from issues such as a limited number of collection trucks, different types of household and industrial waste, and a low number of dumping points. The focus of this paper is on utilizing the available waste collection transportation capacity to efficiently dispose of the waste in a time-efficient manner while maximizing toxic waste disposal. A novel knapsack-based technique is proposed that fills the collection trucks with waste bins from different geographic locations by taking into account the amount of waste and toxicity in the bins using IoT sensors. Using the Knapsack technique, the collection trucks are loaded with waste bins up to their carrying capacity while maximizing their toxicity. The proposed model was implemented in MATLAB, and detailed simulation results show that the proposed technique outperforms other waste collection approaches. In particular, the amount of high-priority toxic waste collection was improved up to 47% using the proposed technique. Furthermore, the number of waste collection visits is reduced in the proposed scheme as compared to the conventional method, resulting in the recovery of the equipment cost in less than a year.

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Interval many‐objective dynamic charging planning in wireless rechargeable sensor networks

Zhang,

Zhao,

et al. 2024

Concurrency and Computation

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SummaryCharging path planning in wireless sensor networks (WSNs) refers to designing an efficient charging path for sensor nodes in the network. However, most charging schemes mainly consider the planning of charging paths and pay little attention to the impact of uncertainties, such as road conditions and environment on the planning of charging paths, as well as ignoring the charging problem of new nodes in need of charging. Road conditions and the environment directly affect the energy consumption of wireless charging vehicles (WCVs) during traveling. To address the aforementioned challenges, this article proposes an interval many‐objective charging path scheme model, the WCV consumption is an uncertain value, it will change according to the environment, and road conditions, so we represent it as an interval parameter with upper and lower bounds. An interval high‐dimensional multi‐objective model with target energy consumption, path distance, number of dead nodes, and communication delay is constructed. Second, to implement this model, an interval SPEA2 algorithm (I‐SPEA2) that introduces an environmental response mechanism is proposed. I‐SPEA2 treats individual target interval values as ranges of values on a two‐dimensional coordinate axis, forming a quadrilateral, calculates individual size probabilities based on the area to determine the dominant relationship, and combines fixed distance and interval overlap to eliminate redundant individuals. The simulation results show that the interval dynamic model is effective in prolonging the lifecycle of WSN as well as the proposed algorithm reduces the mortality rate of the nodes by 15%, 28%, 13%, 16%, and 21% compared with other algorithms.

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Energy-Efficient Multi-Trip Routing for Municipal Solid Waste Collection by Contribution-Based Adaptive Particle Swarm Optimization

Cited by 16 publications

References 39 publications

Challenges and Opportunities for Applying Meta-Heuristic Methods in Vehicle Routing Problems: A Review

Challenges and Opportunities for Applying Meta-Heuristic Methods in Vehicle Routing Problems: A Review

Efficient IoT-Assisted Waste Collection for Urban Smart Cities

Interval many‐objective dynamic charging planning in wireless rechargeable sensor networks

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