EEE spans electric power, machines, power electronics, control, and embedded systems, built on strong math and circuit foundations. Typical early semesters cover circuit theory and networks, electromagnetic fields, analog/digital electronics, electrical measurements, machines-I, and numerical methods, supported by programming and data structures to enable simulation and tooling. Laboratories mirror theory: circuit analysis benches, measurement and instrumentation labs, basic machines labs (DC/AC characteristics), and analog/digital electronics labs. Middle semesters add power systems (generation, transmission, distribution, per-unit models, load flow), machines-II (transformers, induction/synchronous machines), power electronics (converters, inverters, drives), and control systems (modeling, stability, PID/lead-lag design) with MATLAB/Simulink-based control labs and drive test benches. Electives include high-voltage engineering, renewable energy systems, smart grids, electric vehicles and energy storage, microgrids, and protection/relaying, reflecting sector transitions.

Advanced courses extend into power system analysis and protection, HVDC/FACTS, advanced drives, and embedded/real-time systems for power applications. Many curricula specify total credits around 150–170 with structured program outcomes; for example, one public university outlines program-specific outcomes targeting analysis/design of electrical systems and modern tool use, mapped semester-wise to core and lab requirements. Final-year projects commonly involve design and validation of converters/drives, relay coordination, renewable integration studies, or embedded control for motor applications, documented with simulations, hardware tests, and economic/safety analyses. Graduates are prepared for utilities, OEMs, EPC firms, and emerging EV/smart-grid roles.