AI-Driven Inventory Optimization in Retail Supply Chains: Advanced Models, Techniques, and Real-World Applications
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Keywords

artificial intelligence
retail supply chain

How to Cite

[1]
Krishna Kanth Kondapaka, “AI-Driven Inventory Optimization in Retail Supply Chains: Advanced Models, Techniques, and Real-World Applications”, Journal of Bioinformatics and Artificial Intelligence, vol. 1, no. 1, pp. 377–409, May 2021, Accessed: Nov. 22, 2024. [Online]. Available: https://biotechjournal.org/index.php/jbai/article/view/96

Abstract

The ever-evolving landscape of retail necessitates the constant development of sophisticated inventory management strategies that can effectively navigate the intricate interplay between supply and demand. Traditional methods, while providing a foundation, often struggle to keep pace with the complexities inherent in dynamic market conditions, unpredictable consumer behaviors, and the pervasive influence of external factors. This research delves into the transformative potential of artificial intelligence (AI) in revolutionizing inventory optimization within retail supply chains. By harnessing the power of advanced AI models and techniques, this study aims to illuminate innovative approaches that enhance efficiency, reduce costs, and elevate customer satisfaction.

A comprehensive exploration of cutting-edge methodologies, including machine learning, deep learning, and reinforcement learning, is undertaken to elucidate their applicability in various aspects of inventory management. Machine learning algorithms, with their ability to learn from historical data and identify patterns, are particularly adept at forecasting demand with a high degree of accuracy. This empowers retailers to anticipate customer needs and maintain optimal stock levels, minimizing the risk of stockouts and overstocking. Deep learning algorithms, characterized by their complex neural network architectures, excel at processing vast amounts of unstructured data, such as social media sentiment and customer reviews. This enables them to extract valuable insights that can inform inventory planning and product assortment decisions. Reinforcement learning algorithms, through a process of trial and error, can continuously learn and adapt to dynamic environments. This makes them ideal for optimizing inventory placement within warehouses and distribution centers, ensuring efficient picking and fulfillment processes.

Furthermore, the research investigates the potential of integrating AI with emerging technologies such as the Internet of Things (IoT), blockchain, and digital twins to create intelligent and resilient inventory management systems. IoT devices, embedded with sensors and communication capabilities, can provide real-time data on inventory levels, product location, and environmental conditions. This real-time data stream can be leveraged by AI algorithms to dynamically adjust inventory management strategies and optimize resource allocation. For instance, AI can analyze sensor data to predict equipment failures and proactively schedule maintenance, minimizing disruptions to inventory flow. Additionally, AI can utilize real-time location data to optimize picking routes within warehouses, reducing fulfillment times and labor costs.

Blockchain technology, with its core principles of transparency, immutability, and traceability, can enhance supply chain visibility and facilitate secure data sharing between stakeholders. This fosters collaboration and empowers retailers to make informed decisions regarding inventory management throughout the entire supply chain. Imagine a scenario where retailers can leverage blockchain to track the movement of goods in real-time, gaining insights into potential delays or disruptions and enabling them to proactively adjust inventory levels at various stages of the supply chain.

Digital twins, virtual replicas of physical systems, can be integrated with AI to simulate various inventory management scenarios. This enables retailers to test and refine their strategies in a risk-free environment, leading to more informed decision-making and improved operational efficiency. For example, retailers can utilize AI-powered digital twins to simulate the impact of promotional campaigns on inventory demand, allowing them to optimize stock levels and prevent stockouts during peak sales periods.

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References

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