“Fundamentals of Electric Propulsion Systems” introduces the core principles of electric drive systems used in HEVs. Topics include electric motor design, power electronics, and energy conversion processes. Participants gain a comprehensive understanding of electric propulsion and its integration within hybrid vehicles.

“Internal Combustion Engine in HEVs” examines the role of traditional internal combustion engines in hybrid systems. Participants study engine modifications for hybrid applications, fuel efficiency optimization, and emission control strategies to support sustainable transportation.

“Battery Technology for Hybrid Vehicles” covers the principles and technologies behind energy storage in HEVs. The course explores battery chemistries (e.g., lithium-ion, nickel-metal hydride), battery management systems (BMS), and charging techniques. Participants also examine battery safety, thermal management, and lifecycle considerations.

“Power Electronics and Control Systems” focuses on the electronic components responsible for managing power flow in HEVs. Participants learn about inverters, converters, and control algorithms for optimizing energy distribution between the internal combustion engine and electric motor.

“Hybrid Powertrain Architectures” investigates different hybrid configurations, including series, parallel, and power-split systems. The course analyzes the advantages, challenges, and applications of each architecture in various vehicle types and operational environments.

“Energy Management Strategies” explores algorithms and methodologies for optimizing energy consumption in hybrid electric vehicles. Participants examine real-time control systems, regenerative braking, and predictive energy management to enhance vehicle efficiency and performance.

“Vehicle Dynamics and Performance” delves into the interaction between hybrid systems and vehicle motion. Topics include acceleration, handling, braking, and ride comfort. Participants analyze how hybrid technology influences overall vehicle dynamics.

“Thermal Management in HEVs” addresses the critical role of thermal regulation in hybrid vehicles. Participants study cooling systems for electric motors, batteries, and power electronics to ensure efficient operation and system longevity.

“Advanced Driver Assistance Systems (ADAS) in HEVs” explores the integration of smart technologies in hybrid electric vehicles. Topics include adaptive cruise control, regenerative braking coordination, and intelligent energy management. Participants learn how ADAS enhances safety and driving efficiency.

“Hybrid Vehicle Testing and Diagnostics” covers the techniques for assessing and troubleshooting hybrid electric vehicles. Participants study diagnostic tools, fault detection, and performance evaluation. Emphasis is placed on maintenance practices and ensuring optimal vehicle operation.

“Emission Control and Environmental Impact” evaluates the environmental benefits and challenges of hybrid electric vehicles. Participants examine emissions regulations, pollutant reduction techniques, and the lifecycle impact of hybrid technologies on the environment.

“Charging Infrastructure and Energy Policy” addresses the development of hybrid charging systems and their alignment with global energy policies. Participants explore charging technologies, grid integration, and regulatory frameworks shaping the future of hybrid and electric mobility.

“Autonomous and Connected HEVs” investigates the convergence of hybrid electric vehicles with autonomous driving and connectivity. Topics include vehicle-to-everything (V2X) communication, automated driving features, and the role of hybrid systems in future smart mobility solutions.

“Future Trends in Hybrid Electric Vehicles” explores emerging technologies and innovations shaping the next generation of HEVs. Participants study advancements in solid-state batteries, wireless charging, and hybrid applications in new transportation modes.

“Hands-On Projects” is a practical course designed to apply theoretical knowledge to real-world hybrid vehicle scenarios. Participants work on interdisciplinary projects such as hybrid powertrain simulation, energy management systems, and vehicle diagnostics. The course emphasizes collaboration, technical problem-solving, and the development of a professional project portfolio.