Electromagnetic Fields

A Detailed Summary of the Book

The book opens with foundational topics in vector analysis and the essential mathematical tools required to understand electromagnetic fields. A thorough exploration of Maxwell's equations sets the stage for comprehending the behavior of electric and magnetic fields under static and dynamic conditions.

The book also addresses static fields in conductors, dielectrics, and magnetic materials, elucidating their properties and interactions. Special emphasis is given to boundary value problems, ensuring the reader can solve essential field equations for various geometrical and material configurations.

The dynamic portion of the text covers electromagnetic wave propagation, including guided waves in structures like waveguides and transmission lines. In addition, the discussion on electromagnetic radiation and antennas provides crucial insights into how fields are radiated and received, rounding out the text with real-life engineering applications.

With an analytical approach and detailed derivations, Van Bladel diligently examines topics like energy, forces, and computational techniques in field analysis. The text integrates theoretical principles with applied scenarios to bridge the gap between science and engineering practice. Both beginners and experienced professionals will find the structure intuitive, with chapters providing depth, context, and practical solutions.

Key Takeaways

• An in-depth understanding of Maxwell's equations and their applications in engineering and physics.
• Analytical tools for tackling boundary value problems and applying solutions to real-world scenarios.
• An introduction to electromagnetic wave propagation, radiation, and transmission line theory.
• A structured guide to the interactions between electric, magnetic, and dielectric materials under various conditions.
• Advanced concepts like computational electromagnetics, numerical approaches, and energy principles.