High-Resolution Multi-Target DOA Estimation for Resonant Beam Systems
Abstract
Direction of arrival (DOA) estimation technology offers a promising solution to address the sensing and positioning demands of Internet of Things (IoT) devices. Optical resonant beam systems (RBS), owing to their inherent characteristics of self-alignment, self-established energy focusing, and passive target sensing, make them naturally suited for blueDOA estimation in IoT scenarios. However, RBS suffer from limited angular resolution and a narrow field of view (FoV) in multi-target environments. To overcome these limitations, this paper proposes a high-resolution wide-field-of-view resonant beam DOA estimation system (RB-HWDOA). The RB-HWDOA integrates an optical spectrum-based DOA estimation algorithm (OSB-DOA), which leverages amplitude information in the two-dimensional Fourier spectrum of the resonant beam, blueovercoming the resolution limit imposed by the beam size in spatial-domain methods. Furthermore, we designed a bluetelescope modulation (TM) structure to correct phase and direction mismatches, enabling a multi-Tx framework that focuses beams onto a common sensing module, thereby extending the effective FoV. Combined with the OSB-DOA algorithm, this design supports high-resolution DOA estimation for bluemultiple targets simultaneously over a wide FoV. Simulation results show that OSB-DOA resolves angular separations down to 0.1 across multiple resonant beams, remains robust under noise, blueand the TM architecture enables multi-Tx integration for wide-FoV coverage, making RB-HWDOA a scalable and efficient solution for passive multi-target DOA estimation in complex IoT environments.
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