Performance Analysis of In-Band-Full-Duplex Multi-Cell Wideband IAB Networks

The adoption of Matérn hard-core point process impacts network deployment by providing a more realistic model for the spatial arrangement of base stations. Unlike traditional Poisson point processes, which assume random and uniform distribution of nodes, the Matérn hard-core point process introduces repulsion between nodes. This means that in real-world scenarios where base stations cannot be deployed too close to each other due to interference or physical constraints, the Matérn hard-core process better reflects this behavior. By using this model, network planners can optimize base station locations to reduce interference and improve overall network performance.

Hybrid beamforming plays a crucial role in mmWave communications by enabling efficient use of large-scale antenna arrays while minimizing hardware complexity and power consumption. In the context provided, hybrid beamforming is used with subarray structures at gNBs and IAB-nodes to steer beams towards desired users or nodes. This approach allows for spatial multiplexing and beamforming gains without requiring individual RF chains for each antenna element. By leveraging hybrid beamforming techniques, mmWave networks can achieve higher spectral efficiency, lower latency, and improved coverage compared to traditional full digital beamforming methods.

The findings from this study on In-Band-Full-Duplex Multi-Cell Wideband IAB Networks have several implications for enhancing future wireless communication technologies: Improved Capacity: The analysis shows enhanced capacity with outage and ergodic capacity provided by IBFD under successful self-interference cancellation. Cost Reduction: Using MHCPP modeling reduces deployment costs associated with wired connections in multi-cell networks. Performance Optimization: Considering Nakagami-M small fading models along with lognormal shadowing effects provides more accurate channel modeling for mmWave communications. Feasibility Studies: The study paves the way for further research into advanced wireless technologies like 5G and beyond by analyzing system performance under realistic deployment scenarios. Overall, these insights can guide the design and implementation of future wireless networks to meet increasing demands for high data rates, low latency applications, and reliable connectivity across various environments.