Optimizing Spatial Multiplexing in Hybrid Analog-Digital Wide-Aperture MIMO Systems with Spherical Wavefronts

To extend the proposed antenna configuration and beam focusing scheme to handle scenarios with imperfect channel knowledge, we can incorporate robust optimization techniques. By introducing robust optimization into the design process, we can account for uncertainties in the channel state information. This involves formulating the optimization problem with a focus on worst-case scenarios, ensuring that the system's performance is guaranteed even under imperfect channel knowledge. Techniques such as robust beamforming and robust precoding can be employed to mitigate the effects of channel uncertainties. Additionally, adaptive algorithms that continuously update the beamforming weights based on real-time channel feedback can also enhance the system's robustness in the face of imperfect channel knowledge.

The optimal antenna configuration and beam focusing scheme proposed in the study offer significant performance gains in terms of spectral efficiency and spatial multiplexing. However, there are potential tradeoffs to consider, particularly in practical implementation complexity. One tradeoff is the hardware complexity associated with implementing the optimal antenna configuration, especially in large-scale MIMO systems. The precise positioning and alignment of antennas in the proposed configuration may require sophisticated hardware design and calibration processes, increasing the overall system complexity and cost. Additionally, the beam focusing scheme, while effective in maximizing spectral efficiency, may introduce additional computational complexity in real-time signal processing. Balancing the performance gains with the practical constraints of hardware complexity and computational overhead is crucial in determining the feasibility of implementing the proposed scheme in real-world applications.

The insights gained from the study on LoS wide-aperture MIMO systems can be applied to other emerging wireless communication technologies, such as terahertz communications and reconfigurable intelligent surfaces (RIS). In terahertz communications, where high-frequency bands are utilized for high-speed data transmission, the optimal antenna configuration and beam focusing techniques can help maximize spectral efficiency and overcome the challenges posed by high path loss and limited communication range. By adapting the proposed schemes to terahertz communication systems, it is possible to achieve higher data rates and improved link reliability in these advanced communication networks. Similarly, in the context of reconfigurable intelligent surfaces, the principles of optimal antenna configuration and beam focusing can be leveraged to enhance the performance of RIS-assisted communication systems. By optimizing the placement and configuration of intelligent reflecting elements, the system can effectively focus and steer signals to desired locations, improving coverage, signal quality, and overall system capacity. The insights from the study on LoS MIMO can guide the design and deployment of RIS-enabled communication networks, enabling efficient and reliable wireless connectivity in diverse environments.