Dual-Waveguide Pinching Antennas for PLS: Parallel Placement or Orthogonal Placement?

Pinching antennas (PAs), as an emerging flexible-antenna technology, enables movable PAs deployed along waveguides to customize channel conditions over a large scale. This paper investigates an application of PAs to enable physical-layer security (PLS) by enlarging the channel condition diversity between legitimate users (LUs) and eavesdroppers (Eves). Particularly, we focus on the dual-waveguide scenario, where the two waveguides employs multiple PAs to serve multiple LUs in the presence of an Eve. Specifically, we consider two waveguide placement strategies, i.e., parallel placement and orthogonal placement. Meanwhile, we incorporate two channel models, i.e., in-waveguide phase shifts, and in-waveguide phase shifts and attenuation. We formulate the secure sum rate (SSR) and secure energy efficiency (SEE) maximization problems, and propose a two-stage algorithm to solve them. The first stage adopts a particle swarm optimization (PSO) method with an improved feasibility module, termed FeaPSO, for PA placement, and the second stage employs the successive convex approximate (SCA) method to optimize beamforming and artificial noise vectors. Furthermore, we conduct numerical comparisons between the two placement strategies in terms of average performance and a special case where an Eve is positioned in front of LUs. Numerical results validate the effectiveness of the proposed algorithm and demonstrate that PAs can significantly improve both SSR and SEE. Additionally, the necessity of orthogonal waveguide placement is explicitly verified.