This study develops an Operations Management Optimization Model to enhance the strategic positioning of East Port Said within global trade networks. The research integrates statistical analysis, scenario simulation, and mathematical optimization to improve operational efficiency, reduce vessel turnaround time, optimize berth utilization, and minimize operational costs. Data were collected from historical port records, vessel schedules, and cargo throughput, supplemented by simulated scenarios to validate the model. The proposed model uses a Mixed-Integer Linear Programming (MILP) framework for berth allocation, crane assignment, and resource scheduling. Key performance indicators (KPIs) were analysed, including vessel turnaround time, berth utilization, cargo throughput, and operational cost per TEU. Simulation results demonstrate that: Adding 2 additional cranes reduced average vessel turnaround time from 22 ± 4 hours to 18 ± 3.5 hours. Berth utilization increased from 75% ± 8% to 78% ± 6% under optimized allocation. Cargo throughput improved from 10,000 ± 1,200 TEU/day to 11,500 ± 1,100 TEU/day. Operational cost per TEU decreased from $120 to $118. These results confirm that strategic resource allocation and infrastructure improvements significantly enhance port performance. The model provides a decision-support tool for port authorities to optimize operations and strengthen East Port Said’s competitiveness in global maritime trade, while offering insights into efficient logistics planning under variable operational conditions. 

Operations Management, Optimization Model, East Port Said, Port Efficiency, Global Trade Networks, Vessel Turnaround Time, Berth Utilization, Cargo Throughput

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