Beamforming in Coexisting Wireless Systems with Uncertain Channel State Information

T. Le, K. Navaie, Quoc-Tuan Vien, H. Nguyen
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Abstract

This paper considers an underlay access strategy for coexisting wireless networks where the secondary system utilizes the primary spectrum to serve its users. We focus on the practical cases where there is uncertainty in the estimation of channel state information (CSI). Here the throughput performance of each system is limited by the interference imposed by the other, resulting in conflicting objectives. We first analyze the fundamental tradeoff between the tolerance interference level at the primary system and the total achievable throughput of the secondary users. We then introduce a beamforming design problem as a multiobjective optimization to minimize the interference imposed on each of the primary users while maximizing the intended signal received at every secondary user, taking into account the CSI uncertainty. We then map the proposed optimization problem to a robust counterpart under the maximum CSI estimation error. The robust counterpart is then transformed into a standard convex semi-definite programming. Simulation results confirm the effectiveness of the proposed scheme against various levels of CSI estimation error. We further show that in the proposed approach, the trade-off in the two systems modelled by Pareto frontier can be engineered by adjusting system parameters. For instance, the simulations show that at the primary system interference thresholds of -10 dBm (-5 dBm) by increasing number of antennas from 4 to 12, the secondary system throughput is increased by 3.3 bits/s/channel-use (5.3 bits/s/channel-use).
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信道状态信息不确定共存无线系统的波束形成
本文研究了一种共存无线网络的底层接入策略,其中辅助系统利用主频谱为其用户服务。本文重点讨论了信道状态信息估计存在不确定性的实际情况。在这里,每个系统的吞吐量性能受到其他系统施加的干扰的限制,从而导致目标冲突。我们首先分析了主系统的容忍干扰水平与辅助用户的总可实现吞吐量之间的基本权衡。然后,我们引入了一个波束形成设计问题,作为一个多目标优化,以最大限度地减少对每个主要用户施加的干扰,同时最大限度地提高每个辅助用户接收到的预期信号,同时考虑到CSI的不确定性。然后,在最大CSI估计误差下,我们将所提出的优化问题映射到一个鲁棒对应问题。然后将鲁棒拟合物转化为标准凸半定规划。仿真结果验证了该方法对不同程度的CSI估计误差的有效性。我们进一步证明,在所提出的方法中,可以通过调整系统参数来设计由帕累托边界建模的两个系统的权衡。例如,仿真结果表明,在主系统干扰阈值为-10 dBm (-5 dBm)时,通过将天线数量从4个增加到12个,辅助系统吞吐量增加3.3比特/秒/信道使用(5.3比特/秒/信道使用)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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