Theory of Seamless-Scanning Periodic Leaky-Wave Antennas Based on 𝒫𝒯-Symmetry With Time to Space Mapping

Abstract

Periodic leaky wave antennas (P-LWAs) offer highly directive and space-scanning radiation. Unfortunately, they have been plagued by the “broadside issue,” characterized by a degradation in gain when the antenna’s main beam is steered across the broadside. While this issue has been addressed by circuit and network approaches, a related fundamental and general electromagnetic theory has been lacking. This article fills this gap. We first show that a P-LWA is a parity-time-symmetric (PT-symmetric) system, whose even- and odd-mode coupling in the complex space of temporal frequencies leads to the characteristic pair of two-sheet Riemann surfaces. We observe that the branch cuts of these surfaces, which form the well-known PT-symmetric double pitchfork spectrum, correspond to the “balanced frequency” condition, while the branch point at the junction of the pitchforks, is an exceptional point (EP) that corresponds to the “Q-balanced” condition, two conditions that were previously shown to be the conditions for eliminating the broadside issue. In order to acquire an independent and rigorous interpretation of this spectrum, we further transform the coupled complex temporal eigenfrequencies into complex spatial eigenfrequencies. We identify the resulting spatial frequencies as coupled forward-backward modes, with frequency-independent real parts (leakage factors), a condition for P-LWA equalization across broadside. Finally, we derive the scattering parameters of the P-LWA and show that matching is achieved only at one of the two ends of the P-LWA structure. This work both provides a solid foundation to the theory of P-LWAs and represents an original contribution to the field of PT-symmetry.