Theory of Magnetic Transmission Lines

Abstract: This paper presents, for the first time, the frequencydomain theory of magnetic transmission lines, i.e., transmission lines where electromagnetic energy guidance is assured by means of two magnetic-flux carrying parallel magnetic wires, as opposed to the ordinary situation of two current carrying parallel electric wires (an electric transmission line). Propagation equations for the fundamental quasi-TEM mode are established and solved. Wave parameters are analyzed. A transmission matrix is described.

“…As mentioned in [14], it must be emphasized that in the x, y transverse plane, the magnetic field is a purely gradient field ∇ × H = 0 (with open field lines, beginning and ending on different wires), and that the electric displacement vector is a purely solenoidal field ∇ · D = 0 (with closed field lines, embracing one or several wires). In what follows the wire labeled 0 is taken as the reference magnetic wire (where the scalar magnetic potential is arbitrarily set to zero).…”

“…. u N , yielding the result in (2), where g ki are dimensionless real coefficients that only depend on the geometry of the MTL, and where each magnetic voltage [14,19] is defined in (3), the open integration path − → i0 belonging to the transverse plane. Note that in a transverse plane, where H is a gradient field, the concept of magnetic voltage is equivalent to magnetic scalar potential difference.…”

“…Moreover, the pul transverse inductance matrix L T of the MGTL is not to be confused with the familiar pul longitudinal inductance matrix L L of electric MTLs. Nonetheless, for ELTLs and MGTLs sharing the same geometry, matrices L T and L L are intimately correlated (see [14], about the role played by the geometrical factors g). The relationship between matrices L T and L L is given in (9a), where 1 is the identity matrix of rank N .…”

“…In addition to [14][15][16], references to MGTLs can only be found in patent [17] dated of 1968 aimed at transients suppression in a power transformer, and also in a recent patent [18] where future terahertz applications of MGTL are speculated. The theoretical background for two-wire homogeneous magnetic transmission-line analysis has been set in [14], considering the quasi TEM approach. An application of MGTL theory to the analysis of ideal transformers has been provided in [15].…”

“…The contribution of the present paper to advancing the state of the art on MGTL is the extension of the two-wire formalism in [14] to the most general case of multiwire inhomogeneous systems. The multiwire MTL theory is illustrated through numerical simulations concerning a three-wire system with three-fold symmetry, where two degenerate modes (odd and even modes) can be defined.…”

Formulation of Multiwire Magnetic Transmission-Line Theory

“…As mentioned in [14], it must be emphasized that in the x, y transverse plane, the magnetic field is a purely gradient field ∇ × H = 0 (with open field lines, beginning and ending on different wires), and that the electric displacement vector is a purely solenoidal field ∇ · D = 0 (with closed field lines, embracing one or several wires). In what follows the wire labeled 0 is taken as the reference magnetic wire (where the scalar magnetic potential is arbitrarily set to zero).…”

“…. u N , yielding the result in (2), where g ki are dimensionless real coefficients that only depend on the geometry of the MTL, and where each magnetic voltage [14,19] is defined in (3), the open integration path − → i0 belonging to the transverse plane. Note that in a transverse plane, where H is a gradient field, the concept of magnetic voltage is equivalent to magnetic scalar potential difference.…”

“…Moreover, the pul transverse inductance matrix L T of the MGTL is not to be confused with the familiar pul longitudinal inductance matrix L L of electric MTLs. Nonetheless, for ELTLs and MGTLs sharing the same geometry, matrices L T and L L are intimately correlated (see [14], about the role played by the geometrical factors g). The relationship between matrices L T and L L is given in (9a), where 1 is the identity matrix of rank N .…”

“…In addition to [14][15][16], references to MGTLs can only be found in patent [17] dated of 1968 aimed at transients suppression in a power transformer, and also in a recent patent [18] where future terahertz applications of MGTL are speculated. The theoretical background for two-wire homogeneous magnetic transmission-line analysis has been set in [14], considering the quasi TEM approach. An application of MGTL theory to the analysis of ideal transformers has been provided in [15].…”

“…The contribution of the present paper to advancing the state of the art on MGTL is the extension of the two-wire formalism in [14] to the most general case of multiwire inhomogeneous systems. The multiwire MTL theory is illustrated through numerical simulations concerning a three-wire system with three-fold symmetry, where two degenerate modes (odd and even modes) can be defined.…”

Formulation of Multiwire Magnetic Transmission-Line Theory

Magnetic charge, magnetic current, magnetic scalar potential, and electric vector potential

A physical model of the ideal transformer based on magnetic transmission line theory