OPTIMIZING SUPPLY CHAIN EFFICIENCY THROUGH MACHINE LEARNING-DRIVEN PREDICTIVE ANALYTICS

Abstract

The complexities of modern supply chains present significant challenges in maintaining efficiency, reducing operational costs, and adapting to market fluctuations. Traditional supply chain management approaches often struggle to anticipate disruptions and align with dynamic demand patterns, leading to costly inefficiencies and suboptimal decision-making. This paper explores the integration of machine learning-driven predictive analytics as a transformative solution for optimizing supply chain efficiency. By leveraging diverse data sources—such as historical demand, real-time inventory levels, transportation data, and external factors like weather or economic indicators—machine learning models can uncover patterns, forecast demand, and streamline inventory management. Key methodologies examined include time series forecasting, classification algorithms for demand and supply adjustments, and clustering techniques to identify optimal stock levels and transportation routes. The research further evaluates model performance using accuracy, mean absolute error, and precision metrics to determine the effectiveness of different predictive models in real-world applications. Through case studies in manufacturing and retail supply chains, we demonstrate how predictive analytics can improve inventory management, reduce lead times, and increase resilience against supply chain disruptions. This study provides insights into the practical implementation of machine learning in supply chain systems, outlines challenges related to data quality and model interpretability, and suggests directions for future research, emphasizing the potential of predictive analytics to drive cost-efficiency and responsiveness in global supply networks.