Sub-6-GHz Uplink Massive MIMO System Using Holographic Beamforming Metasurfaces: A Conceptual Development

We propose an uplink massive MIMO system using an array of holographic metasurfaces as a sector antenna operating at 3.5 GHz. The antenna consists of a set of rectangular waveguide-fed metasurfaces combined along the elevation direction into a planar aperture, each with subwavelength-sized metamaterial elements as radiators. The metamaterial radiators are designed such that the waveguide-fed metasurface implements a holographic solution for the guided (or reference) mode, generating a directional beam towards a prescribed direction, thereby forming a multibeam antenna system. We demonstrate that a narrowband uplink massive MIMO system using the metasurfaces can achieve the sum capacity close to that offered by the Rayleigh channel. We show that metasurfaces supporting multiple beams can achieve high spatial resolution in the azimuth directions in sub-6 GHz channels, and thereby form uncorrelated MIMO channels between the base station and users. Also, the proposed metasurface antenna is structurally simple, low-cost, and efficient, and thus is suitable to alleviate RF hardware issues common to massive MIMO systems equipped with a large antenna system.

Automated summary

We propose an uplink massive MIMO system using holographic metasurfaces as a sector antenna operating at 3.5 GHz. The antenna consists of rectangular waveguide-fed metasurfaces combined into a planar aperture, each with subwavelength-sized metamaterial elements as radiators. The metasurfaces support multiple beams and achieve high spatial resolution in the azimuth directions, forming uncorrelated MIMO channels between the base station and users. The proposed metasurface antenna is structurally simple, low-cost, and efficient, suitable for addressing RF hardware issues in massive MIMO systems.