This is the first book to offer a comprehensive exploration of new methods in inverse problems in electromagnetics. The text provides a wealth of systematic descriptions of the most important practical inverse problems, and details new methods to solve them.

This is the first book on the topic of new methods in inverse problems in electromagnetics. The inverse problems such as optimization, synthesis, diagnostics, and identification are becoming one of the most important subjects in the field because of the significant practical applications to electric circuits and electromagnetics. This book introduces recent achievements in mathematics and computing. The information on how to use the modern theoretical ideas and methods to solve inverse problems will help both students and specialists. The book systematically treats modern mathematic methods of inverse problems solution by providing descriptions of the most important practical inverse problems and the methods to solve them. Included also are descriptions of the properties of inverse problems and known methods of their solution as well as the practical implementation of these methods in electric circuits theory and electromagnetic fields theory.

Inverse Problems in Electrical Circuits and Electromagnetic Field Theory.- The Methods of Optimization Problems Solution.- Methods of Solution of Stiff Inverse Problems.- Solving Inverse Electromagnetic Problems by the Lagrange Method.- Solving Practical Inverse Problems.

The design and development of electrical devices involves choosing from many possible variants that which is the best or optimum according to one or several criteria. These optimization criteria are usually already clear to the designer at the statement of the design problem. The methods of optimization considered in this book, allow us to sort out variants of the realization of a design on the basis of these criteria and to create the best device in the sense of the set criteria. Optimization of devices is one of the major problems in electrical engi neering that is related to an extensive class of inverse problems including synthesis, diagnostics, fault detection, identification, and some others with common mathematical properties. When designing a device, the engineer ac tually solves inverse problems by defining the device structure and its pa rameters, and then proceeds to deal with the technical specifications followed by the incorporation of his own notions of the best device. Frequently the so lutions obtained are based on intuition and previous experience. New meth ods and approaches discussed in this book will add mathematical rigor to these intuitive notions. By virtue of their urgency inverse problems have been investigated for more than a century. However, general methods for their solution have been developed only recently. An analysis of the scientific literature indicates a steadily growing interest among scientists and engineers in these problems.