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Advanced Superdirective Antennas

Optics 2026-02-05 v1 Applied Physics

Abstract

Superdirective (supergain) antennas aim to produce a narrow main beam from radiators that are electrically small compared with the wavelength. Instead of enlarging the physical aperture, they rely on strongly coupled currents, near-field energy storage, and controlled modal interference so that a compact structure radiates with enhanced directivity. This review emphasizes link-relevant evaluation and reporting: realized gain referenced to a stated impedance plane, clearly stated bandwidth definitions (impedance and performance), and robustness to fabrication spread and platform/environmental loading. Two practical implementation routes are surveyed. The first uses resonant, tightly coupled arrays, including fully driven arrays and single-chain designs based on parasitic or reactively loaded elements. The second uses single-body radiators that enforce a targeted mixture of multipoles or resonant/characteristic modes with one or a few feeds, including symmetry-broken dielectric resonators and mixed electric--magnetic designs. Across RF, microwave, and optical regimes, the same penalties recur as superdirectivity is pushed: reduced radiation resistance, rapid impedance variation, narrow usable bandwidth, and strong sensitivity to small perturbations. Beyond geometric synthesis and multi-resonant stacking, the review highlights emerging levers that can shift these trade-offs in specific system contexts: low-loss materials and cryogenic operation to improve efficiency and frequency stability, and time-varying loading and matching (Floquet/parametric approaches) that can relax linear time-invariant bandwidth constraints, at the cost of added control complexity and spectral conversion.

Keywords

Cite

@article{arxiv.2602.04121,
  title  = {Advanced Superdirective Antennas},
  author = {Alex Krasnok},
  journal= {arXiv preprint arXiv:2602.04121},
  year   = {2026}
}
R2 v1 2026-07-01T09:35:14.475Z