Sparse Fluid Antenna Arrays: Continuous Position Design Beyond Classical DOF Limits

Abstract

Fluid antenna system (FAS), which continuously repositions a single physical element across a deployment region [0, D], breaks this limit by freeing antenna positions from the discrete grid entirely. This paper establishes the theoretical foundations of sparse FAS design for direction-of-arrival (DOA) estimation and shows that continuous position freedom unlocks three compounding advantages over the classical designs. First, we derive a universal dual DOF bound and prove that FAS-optimized positions can approach it, growing the DOF linearly with D/λ , where λ is the signal wavelength, rather than saturating at O(N2). Second, the CRB scales as O(1/D2L) for L sources, a (D/(N2 d0))2L improvement over the best grid design, with d0 = λ/2 and D-optimal positions admitting closed-form solution for single sources and efficient Frank-Wolfe algorithm for multiple sources. Third, we propose a two-stage FAS-MUSIC approach that combines coarray MUSIC disambiguation with full-aperture local maximum likelihood (ML) refinement to track the CRB, overcoming the grating-lobe ambiguity inherent in large-aperture non-uniform arrays. Robustness to minimum spacing constraints, mutual coupling, and finite position accuracy is also analyzed. Extensive simulations show that FAS-MUSIC achieves 17.5× lower root mean squared error (RMSE) than uniform linear array (ULA) MUSIC and that FAS with 4 antennas outperforms MRA with 8 antennas, gains that are unattainable by any grid-constrained design.