Advanced Antenna Array Engineering for 6G and Beyond Wireless Communications. Richard W. Ziolkowski

Advanced Antenna Array Engineering for 6G and Beyond Wireless Communications - Richard W. Ziolkowski


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are based simply on geometrical optics and point source assumptions. For actual antenna designs at mm‐wave and THz frequencies, optimization of the cylindrical extension would be required to achieve the optimal radiation performance [26, 27].

Schematic illustration of Fresnel lenses. (a) Original Fresnel lens. (b) Circular phase correcting version.

      Source: Modified from [25] / IEEE.

      One salient advantage of the Fresnel lens is its low profile. On the other hand, its main disadvantage is its relatively narrow bandwidth. Nevertheless, substantial progress has been made to increase the bandwidth of transmit arrays in recent years [30]. It should be pointed out that although a Fresnel lens can be made flat, it still needs a feed typically placed many wavelengths away from the lens. If the required beamwidth is not too narrow, one can achieve a completely flat version, i.e., a metasurface‐based antenna that is created by placing a metasurface above an antenna backed by a ground plane [31].

Schematic illustration of (a) SIMO and (b) MIMO multi-beam antennas.

      Notice that the SIMO and MIMO multi‐beam antenna concepts presented above are substantially different from the concepts of SIMO and MIMO in wireless communication systems. All of the inputs and outputs in the former reside in one transmitter or receiver system, typically in the base stations. The multi‐beams produced by the antennas are distinct beam patterns. In contrast, all of the inputs and outputs of the latter reside separately in the transmitter, typically at the base station, and the receivers, typically in the user terminals. The transmitted RF signal may not have distinct conventional beam patterns; certain types of multiuser detection or spatial–temporal decoding algorithms are employed at the receivers with no regard to specific beam patterns.

      As frequency resources become more and more scarce, the issue of spectral efficiency has become a top priority for future generations of wireless communication systems. Consequently, in‐band full‐duplex (IBFD) radios are widely regarded as a key technology for the evolution of 5G and 6G systems. IBFD radios allow signal transmission and reception in the same frequency band and at the same time [32]. IBFD radios can double the data rate without using more frequency bands or more time, thus resulting in unprecedented spectrum efficiency enhancement. However, one major issue existing in full‐duplex radios is the suppression of in‐band self‐interference between the transmitters and receivers caused by mismatching at their ports, the mutual coupling between their antenna elements, and the scattering from objects in the environment in which they actually must work.

      Clearly, no digital circuits can operate without adequate isolation and appropriate cancelations in the antenna and analog domains to bring the signal‐to‐noise‐and‐interference ratio down to an acceptable level. To this end, major efforts have been made in analog cancelation methods using adaptive circuits and antennas [34–37]. Reported antenna solutions aim to increase the isolation between the transmitter and receiver ports by virtue of spatial and polarization separation, use of metamaterials, and beam squinting. In principle, an ideal solution would be a combination of antenna‐decoupling techniques to be discussed in Chapter 3 and self‐interference cancelation circuits. Major challenges facing antenna researchers and engineers are wide bandwidth, limited antenna space, and low‐loss circuit designs.

      Up until the emergence of the third‐ and fourth‐generation mobile wireless communication networks, the focus of most antenna researchers was largely on antennas for radar and satellite communications. On the other hand, antenna designers working in the mobile communication industry were faced with “engineering” challenges largely ignored by the majority of academic antenna researchers. The collocation and coexistence of antennas for 3G and 4G, as well as the demand for antenna miniaturization and stringent specifications, posed serious research challenges to the antenna community. However, judging by the number of publications, one may argue that base station antennas and terminal antennas did not receive the attention they deserved from academic researchers. This lack of attention might have been partly attributed to the unique global industrial landscape formed in that period; the industry was consolidated to only a few players in the end. Moving forward to 5G and 6G, the technology competition among national governments and industries from all around the globe is rapidly gathering pace, thus attracting the widespread interest of the international antennas community. As a result, research on 5G and 6G antennas has started taking center stage globally. In this chapter, we have provided our own perspectives for 5G and 6G antennas. We have outlined some of the major challenges facing antenna researchers and designers, and have enunciated possible technology


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