Impact of E-plane Misalignment on THz Diagonal Horn Antennas

TL;DR

This study investigates how E-plane misalignment affects the performance of THz diagonal horn antennas, emphasizing the need for precise alignment to ensure optimal coupling efficiency in terahertz systems.

Contribution

The paper provides a comprehensive analysis combining theory, simulation, and experiments to quantify alignment tolerances for E-plane split diagonal horn antennas in the 325-500 GHz range.

Findings

Minor geometric asymmetries increase cross-polar radiation.

8% wavelength misalignment causes 3-dB coupling degradation.

Analytical and experimental results show strong agreement.

Abstract

A key challenge in developing terahertz front-ends is achieving high coupling efficiency between the waveguide feed horn and the optical beam. In this paper, we have quantified the alignment requirements for the widely used E-plane split diagonal horn antenna through theoretical analysis, electromagnetic simulation, and experimental validation within the 325-500 GHz frequency range. The results from our analytical models, simulations, and measurements are consistent and shows good agreement. They reveal that even minor geometric asymmetries can cause significant increases in fractional power radiated to the cross-polar component due to amplitude and phase imbalances in the TE10 and TE01 modes. Furthermore, a misalignment of approximately 8% of the wavelength was observed to result in a 3-dB degradation in the optical coupling to a Gaussian beam (Gaussicity) in middle of the waveguide band. These findings highlight the critical importance of precise alignment and feed horn machining for the successful implementation of terahertz front-end systems.