Intelligent Reflecting Surface Enhanced Wireless Network: Two-timescale Beamforming Optimization

TL;DR

This paper introduces a two-timescale beamforming optimization method for IRS-enhanced wireless networks, reducing channel training overhead by leveraging statistical CSI for passive beamforming and instantaneous CSI for active transmission.

Contribution

It proposes a novel two-timescale protocol that optimizes IRS phase-shifts based on statistical CSI and transmit beamforming based on instantaneous CSI, improving efficiency and performance.

Findings

Significant sum-rate improvement demonstrated in simulations.

Reduced channel training overhead compared to existing methods.

Effective IRS phase-shift optimization under correlated Rician channels.

Abstract

Intelligent reflecting surface (IRS) has drawn a lot of attention recently as a promising new solution to achieve high spectral and energy efficiency for future wireless networks. By utilizing massive low-cost passive reflecting elements, the wireless propagation environment becomes controllable and thus can be made favorable for improving the communication performance. Prior works on IRS mainly rely on the instantaneous channel state information (I-CSI), which, however, is practically difficult to obtain for IRS-associated links due to its passive operation and large number of elements. To overcome this difficulty, we propose in this paper a new two-timescale (TTS) transmission protocol to maximize the achievable average sum-rate for an IRS-aided multiuser system under the general correlated Rician channel model. Specifically, the passive IRS phase-shifts are first optimized based on the statistical CSI (S-CSI) of all links, which varies much slowly as compared to their I-CSI, while the transmit beamforming/precoding vectors at the access point (AP) are then designed to cater to the I-CSI of the users' effective channels with the optimized IRS phase-shifts, thus significantly reducing the channel training overhead and passive beamforming complexity over the existing schemes based on the I-CSI of all channels. For the single-user case, a novel penalty dual decomposition (PDD)-based algorithm is proposed, where the IRS phase-shifts are updated in parallel to reduce the computational time. For the multiuser case, we propose a general TTS optimization algorithm by constructing a quadratic surrogate of the objective function, which cannot be explicitly expressed in closed-form. Simulation results are presented to validate the effectiveness of our proposed algorithms and evaluate the impact of S-CSI and channel correlation on the system performance.