Mathematical modeling is vital when understanding and optimizing machine transport dynamics. By applying principles from physics, engineering, and mathematics, these models simulate real-world transport behaviors, such as acceleration, friction, load distribution, and system response. This enables researchers and engineers to predict performance, identify areas of improvement, and design more efficient and reliable transport mechanisms. As industries rely on automation and smart machinery, mathematical modeling becomes essential for advancing precision, safety, and innovation in transport system design.
Mathematical Modeling in Machine Transport Dynamics explores the development of the scientific and methodological basis of modern mechanical engineering, formed by machine science, applied mechanics, the theory of mechanisms and machines, vibration theory, applied system analysis, and the theory of automatic control. It examines the technical facilities for technological and transport purposes operating under conditions of intensive dynamic loading. This book covers topics such as machine theory, mechanical systems, and transportation engineering, and is a useful resource for business owners, engineers, academicians, researchers, and scientists.