A Review: Machine Learning for Combinatorial Optimization Problems in Energy Areas

Yang, Xinyi; Wang, Ziyi; Zhang, Hengxi; Ma, Nan; Yang, Ning; Liu, Hualin; Zhang, Haifeng; Yang, Lei

doi:10.3390/a15060205

Cited by 18 publications

(11 citation statements)

References 229 publications

(302 reference statements)

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“…Oil and gas companies have complex supply chains with data spread across different systems and formats, making data integration challenging (Tirkolaee, et. al., 2021, Yang, et. al., 2022.…”

Section: Challenges and Considerationsmentioning

confidence: 99%

Machine Learning's Influence on Supply Chain and Logistics Optimization in the Oil and Gas Sector: A Comprehensive Analysis

Agnes Clare Odimarha,

Sodrudeen Abolore Ayodeji,

Emmanuel Adeyemi Abaku

2024

Comput. sci. IT res. j.

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Machine Learning (ML) is revolutionizing supply chain and logistics optimization in the oil and gas sector. This comprehensive analysis explores how ML algorithms are reshaping traditional practices, leading to more efficient operations and cost savings. ML enables predictive analytics, demand forecasting, route optimization, and inventory management, improving overall supply chain performance. Supply chain and logistics in the oil and gas sector are inherently complex, involving numerous interconnected processes and stakeholders. ML algorithms are adept at handling this complexity by analyzing vast amounts of data to identify patterns and optimize operations. By leveraging historical data, ML can predict future demand, enabling companies to adjust their inventory levels and production schedules accordingly. ML algorithms also play a crucial role in route optimization, helping companies minimize transportation costs and reduce carbon emissions. By analyzing factors such as traffic patterns, weather conditions, and road conditions, ML algorithms can determine the most efficient routes for transporting goods and equipment. Furthermore, ML enables predictive maintenance, which is essential in the oil and gas sector to prevent equipment failures and downtime. By analyzing sensor data from equipment, ML algorithms can predict when maintenance is required, allowing companies to schedule maintenance proactively and avoid costly disruptions. In conclusion, ML is transforming supply chain and logistics optimization in the oil and gas sector by enabling predictive analytics, demand forecasting, route optimization, and predictive maintenance. By leveraging the power of ML, companies in the oil and gas sector can improve operational efficiency, reduce costs, and enhance overall supply chain performance. Keywords: Machine’s Learning, Supply Chain, Logistics, Optimization, Oil and Gas.

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“…Oil and gas companies have complex supply chains with data spread across different systems and formats, making data integration challenging (Tirkolaee, et. al., 2021, Yang, et. al., 2022.…”

Section: Challenges and Considerationsmentioning

confidence: 99%

Machine Learning's Influence on Supply Chain and Logistics Optimization in the Oil and Gas Sector: A Comprehensive Analysis

Agnes Clare Odimarha,

Sodrudeen Abolore Ayodeji,

Emmanuel Adeyemi Abaku

2024

Comput. sci. IT res. j.

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“…The fusion of ACO, ML, and Fuzzy Logic in inventory management aligns seamlessly with the principles of information sharing and interoperability within supply chains, echoing the sentiments of Khan and Abonyi (2022), particularly in the context of the burgeoning circular economy. Amidst a world where computational intelligence and optimization techniques hold increasing prominence, this integrated approach resonates with the trend of harnessing machine learning for solving combinatorial optimization problems, as discerned from the work of Yang et al (2022). This synthesis harmonizes with comprehensive efforts geared towards sustainably optimizing manufacturing processes through computational intelligence, as illuminated in "Computational Intelligence based Optimization of Manufacturing Process for Sustainable Materials" (Sinwar et al, 2023).…”

Section: Introductionmentioning

confidence: 99%

An Integrated Approach of Ant Colony Optimization (ACO), Machine Learning (ML), and Fuzzy Logic for Revolutionizing Inventory Management in Modern Supply Chains

S. Swathi, K. Kalaiarasi

2023

tjjpt

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This article presents a groundbreaking approach aimed at addressing the limitations of conventional inventory management practices in contemporary supply chains. The principal objective is to revolutionize inventory management by harnessing the synergistic potential of Ant Colony Optimization (ACO), Machine Learning (ML), and Fuzzy Logic. This integrated framework seeks to elevate demand forecasting, optimize ordering strategies, and enhance inventory control processes. Methods: The methodology encompasses the amalgamation of three potent techniques: ACO for the optimization of reorder points and quantities, ML for precise demand forecasting through the analysis of historical data and external variables, and Fuzzy Logic for managing imprecise and linguistic factors to facilitate adaptable decision-making. This fusion minimizes overall inventory costs while refining inventory-related choices. Findings: The fusion of ACO, ML, and Fuzzy Logic represents a pragmatic solution for contemporary inventory management. Businesses that embrace this approach can attain adaptability, data-driven precision, and flexibility, resulting in improved demand forecasting, optimized ordering strategies, and more efficient inventory management processes. An illustrative real-world case demonstrates that this integrated approach leads to cost-effective and responsive solutions, with the potential to revolutionize inventory management, translating into cost savings, heightened customer satisfaction, and enhanced operational efficiency. Novelty: The novelty of this integrated approach lies in its distinctive amalgamation of ACO, ML, and Fuzzy Logic within the inventory management context. While these techniques are well-established in their own right, their integration signifies an innovative response to an enduring challenge. This approach enables adaptability to shifting conditions, precise demand forecasting, and flexible decision-making, which were arduous to achieve using traditional methodologies.

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“…This methodology models business challenges as Markov decision processes and learns policies that maximize cumulative rewards through sustained interaction with the environment. Its core strengths lie in its neural-network-based approximation capabilities, rapid sequential decision making, and a degree of adaptability in addressing dynamic programming challenges [13]. Yet, when applied to actual industrial problems, these methods often grapple with expansive state spaces, extended training durations, and convergence difficulties [14], signaling the need for more efficient methods.…”

Section: Introductionmentioning

confidence: 99%

State-Space Compression for Efficient Policy Learning in Crude Oil Scheduling

Ma,

Li,

Liu

2024

Mathematics

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The imperative for swift and intelligent decision making in production scheduling has intensified in recent years. Deep reinforcement learning, akin to human cognitive processes, has heralded advancements in complex decision making and has found applicability in the production scheduling domain. Yet, its deployment in industrial settings is marred by large state spaces, protracted training times, and challenging convergence, necessitating a more efficacious approach. Addressing these concerns, this paper introduces an innovative, accelerated deep reinforcement learning framework—VSCS (Variational Autoencoder for State Compression in Soft Actor–Critic). The framework adeptly employs a variational autoencoder (VAE) to condense the expansive high-dimensional state space into a tractable low-dimensional feature space, subsequently leveraging these features to refine policy learning and augment the policy network’s performance and training efficacy. Furthermore, a novel methodology to ascertain the optimal dimensionality of these low-dimensional features is presented, integrating feature reconstruction similarity with visual analysis to facilitate informed dimensionality selection. This approach, rigorously validated within the realm of crude oil scheduling, demonstrates significant improvements over traditional methods. Notably, the convergence rate of the proposed VSCS method shows a remarkable increase of 77.5%, coupled with an 89.3% enhancement in the reward and punishment values. Furthermore, this method substantiates the robustness and appropriateness of the chosen feature dimensions.

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A Review: Machine Learning for Combinatorial Optimization Problems in Energy Areas

Cited by 18 publications

References 229 publications

Machine Learning's Influence on Supply Chain and Logistics Optimization in the Oil and Gas Sector: A Comprehensive Analysis

Machine Learning's Influence on Supply Chain and Logistics Optimization in the Oil and Gas Sector: A Comprehensive Analysis

An Integrated Approach of Ant Colony Optimization (ACO), Machine Learning (ML), and Fuzzy Logic for Revolutionizing Inventory Management in Modern Supply Chains

State-Space Compression for Efficient Policy Learning in Crude Oil Scheduling

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