Vehicle dynamics is the study of how vehicles move, handle, and respond to various forces and conditions. It is crucial for designing, engineering, and operating safe, efficient, and high-performing automobiles. The course explores the forces that influence a vehicle's behavior and performance while on the move. It focuses on three fundamental forces: aerodynamic drag, gradient resistance, and rolling resistance. Aerodynamic drag is explored in depth, providing insights into optimizing car design for improved fuel efficiency and reduced air resistance. Gradient resistance is examined, emphasizing the importance of gravity and inclines in real-world driving situations. Strategies for minimizing rolling resistance are discussed, promoting a comprehensive understanding of tire and road contact impacting vehicle efficiency. The course also covers the vehicle’s torque, power, and energy requirements, allowing students to compute torque and power for specific acceleration goals. This knowledge empowers them to optimize engine performance in different driving scenarios and aligns theoretical concepts with practical applications within the mobility industry. By the end of this course, participants will have a solid understanding of the forces affecting a vehicle's route as well as the precise calculations required to maintain optimal vehicle performance. This knowledge enables them to excel in a variety of professions in the automotive and mobility industries, where knowing these principles is critical for innovation and growth.