Abstract Objective: To develop a data-driven framework for accurately assessing, forecasting, and optimizing electricity consumption in educational institutions to support efficient energy management, cost reduction, and campus-scale sustainability planning. Method: detailed inventories of electrical loads were prepared for B and C blocks of Methodist College of Engineering and Technology, Hyderabad, India in the academic year 2024-25 by documenting appliance types, rated capacities, quantities, locations, and operating schedules, which were used to model daily and monthly demand patterns; to handle heterogeneous and non-linear consumption behaviour driven by occupancy, academic timetables, equipment diversity, and seasonal effects, a Random Forest Regression model was trained on historical measurements and evaluated using structured validation procedures, including cross-validation and standard statistical error metrics, to support both short-term load forecasting for operations and longer-term demand estimation for capacity planning. Findings: the proposed framework successfully characterized consumption behaviour across classrooms, laboratories, offices, and shared facilities, revealing strong temporal and spatial variability, with clear peak-demand windows, off-peak opportunities, and seasonal fluctuations linked to academic schedules. Novelty: this study integrates block-level, equipment-wise load auditing with machine-learning-based forecasting to generate actionable efficiency insights under real operational conditions, making the approach scalable for large campuses and adaptable to automated metering and continuous monitoring Keywords: Load Forecasting, Energy Management, Machine Learning, Power Consumption Analysis, Educational Campuses
Namburi Nireekshana (Fri,) studied this question.