This paper investigates unmanned aerial vehicle (UAV)-mounted intelligent
reflecting surfaces (IRS) to leverage the benefits of this technology for
future communication networks, such as 6G. Key advantages include enhanced
spectral and energy efficiency, expanded network coverage, and flexible
deployment. One of the main challenges in employing UAV-mounted IRS (UMI)
technology is the random fluctuations of hovering UAVs. Focusing on this
challenge, this paper explores the capabilities of UMI with passive/active
elements affected by UAV fluctuations in both horizontal and vertical angles,
considering the three-dimensional (3D) radiation pattern of the IRS. The
relationship between UAV fluctuations and IRS pattern is investigated by taking
into account the random angular vibrations of UAVs. A tractable and closed-form
distribution function for the IRS pattern is derived, using linear
approximation and by dividing it into several sectors. In addition, closed-form
expressions for outage probability (OP) are obtained using central limit
theorem (CLT) and Gamma approximation. The theoretical expressions are
validated through Monte Carlo simulations. The findings indicate that the
random fluctuations of hovering UAVs have a notable impact on the performance
of UMI systems. To avoid link interruptions due to UAV instability, IRS should
utilize fewer elements, even though this leads to a decrease in directivity. As
a result, unlike terrestrial IRS, incorporating more elements into aerial IRS
systems does not necessarily improve performance due to the fluctuations in
UAV. Numerical results show that the OP can be minimized by selecting the
optimal number of IRS elements and using active elements.

Este artículo explora los viajes en el tiempo y sus implicaciones.

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