Electromagnetic Field Theory in $(N+1)$ -Space-Time: A Modern Time-Domain Tensor/Array Introduction

In this paper, a modern time-domain introduction is presented for electromagnetic field theory in (N+1)-space-time. It uses a consistent tensor/array notation that accommodates the description of electromagnetic phenomena in N-dimensional space (plus time), a requirement that turns up in present-day theoretical cosmology, where a unified theory of electromagnetic and gravitational phenomena is aimed at. The standard vectorial approach, adequate for describing electromagnetic phenomena in (3+1)-space-time, turns out to be not generalizable to (N+1)-space-time for N >; 3 and the tensor/array approach that, in fact, has been introduced in Einstein's theory of relativity, proves, together with its accompanying notation, to furnish the appropriate tools. Furthermore, such an approach turns out to lead to considerable simplifications, such as the complete superfluousness of standard vector calculus and the standard condition on the right-handedness of the reference frames employed. Since the field equations do no more than interrelate (in a particular manner) changes of the field quantities in time to their changes in space, only elementary properties of (spatial and temporal) derivatives are needed to formulate the theory. The tensor/array notation furthermore furnishes indications about the structure of the field equations in any of the space-time discretization procedures for time-domain field computation. After discussing the field equations, the field/source compatibility relations and the constitutive relations, the field radiated by sources in an unbounded, homogeneous, isotropic, lossless medium is determined. All components of the radiated field are shown to be expressible as elementary operations acting on the scalar Green's function of the scalar wave equation in (N+1) -space-time. Time-convolution and time-correlation reciprocity relations conclude the general theory. Finally, two items on field computation are touched upon: the space-time-integrated field equations method of computation and the time-domain Cartesian coordinate stretching method for constructing perfectly matched computational embeddings. The performance of these items is illustrated in a demonstrator showing the 1-D pulsed electric-current and magnetic-current sources excited wave propagation in a layered medium.

[1]  E. C. Titchmarsh,et al.  The Laplace Transform , 1991, Heat Transfer 1.

[2]  A. P. Wills,et al.  The Theory of Electrons and Its Applications to the Phenomena of Light and Radiant Heat , 1910 .

[3]  E. Michielssen,et al.  Time Domain CalderÓn Identities and Their Application to the Integral Equation Analysis of Scattering by PEC Objects Part II: Stability , 2009, IEEE Transactions on Antennas and Propagation.

[4]  P. Dirac Quantised Singularities in the Electromagnetic Field , 1931 .

[5]  Peter M. van den Berg,et al.  The 3D wave equation and its Cartesian coordinate stretched perfectly matched embedding - A time-domain Green's function performance analysis , 2007, J. Comput. Phys..

[6]  B. Kosyakov ELECTROMAGNETIC RADIATION IN EVEN-DIMENSIONAL SPACE–TIMES , 2008, 0803.3304.

[7]  P. Lugol Annalen der Physik , 1906 .

[8]  A. T. de Hoop Electromagnetic Field Theory in $(N+1)$ -Space-Time: A Modern Time-Domain Tensor/Array Introduction , 2013, Proceedings of the IEEE.

[9]  P. Yla-Oijala,et al.  Calderon Preconditioned Surface Integral Equations for Composite Objects With Junctions , 2011, IEEE Transactions on Antennas and Propagation.

[10]  A. T. Hoop Handbook of radiation and scattering of waves , 1995 .

[11]  H. W. Bode,et al.  Network analysis and feedback amplifier design , 1945 .

[12]  Adrian Doicu,et al.  Light Scattering by Systems of Particles , 2006 .

[13]  C. Oseen Über die Wechselwirkung zwischen zwei elektrischen Dipolen und üer die Drehung der Polarisationsebene in Kristallen und Flüssigkeiten , 1915 .

[14]  E. Michielssen,et al.  Time Domain CalderÓn Identities and Their Application to the Integral Equation Analysis of Scattering by PEC Objects Part I: Preconditioning , 2009, IEEE Transactions on Antennas and Propagation.

[15]  Ludwig Boltzmann,et al.  Zur Theorie der elastischen Nachwirkung , 1878 .

[16]  A. T. Hoop The initial-value problems in acoustics, elastodynamics and electromagnetics , 1996 .

[17]  H. Piaggio The Mathematical Theory of Huygens' Principle , 1940, Nature.

[18]  G. I. Kustova,et al.  From the author , 2019, Automatic Documentation and Mathematical Linguistics.

[19]  Reciprocity, discretization, and the numerical solution of direct and inverse electromagnetic radiation and scattering problems , 1991 .

[20]  Weng Cho Chew,et al.  A 3D perfectly matched medium from modified maxwell's equations with stretched coordinates , 1994 .