The paper principally proposes a suboptimally closed-form solution in terms of a general asymptotic bound of the secrecy capacity in relation to MIMOME-based transceivers. Such pivotal solution is essentially tight as well, fundamentally originating from the principle convexity. The resultant novelty, per se, is strictly necessary since the absolutely central criterion imperfect knowledge of the wiretap channel at the transmitter should also be highly regarded. Meanwhile, ellipsoidal channel uncertainty set-driven strategies are physically taken into consideration. Our proposed solution is capable of perfectly being applied for other general equilibria such as multiuser ones. In fact, this in principle addresses an entirely appropriate alternative for worst-case method-driven algorithms utilising some provable inequality-based mathematical expressions. Our framework is adequately guaranteed regarding a totally acceptable outage probability (as 1 - preciseness coefficient). The relative value is almost 10% for the estimation error values (EEVs) = 0.5 for 2 x 2-based transceivers, which is noticeably reinforced at nearly 5% for EEVs = 0.9 for the case 4 x 4. Furthermore, our proposed scheme basically guarantees the secrecy outage probability (SOP) less than 0.05% for the case of having EEVs = 0.3, for the higher power regime.
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机译:本文主要针对与基于MIMOME的收发器有关的保密容量的一般渐近边界,提出了一种次优封闭形式的解决方案。这种关键解决方案也基本上是严格的,其根本原因是原则上的凸性。从本质上讲,由此产生的新颖性是绝对必要的,因为也应该高度重视发射机的窃听通道的绝对中心标准的不完善知识。同时,在物理上考虑椭圆形通道不确定性集驱动策略。我们提出的解决方案能够完美地应用于其他一般均衡,例如多用户均衡。实际上,这原则上解决了使用一些可证明的基于不等式的数学表达式的最坏情况方法驱动算法的完全合适的替代方法。对于完全可接受的中断概率(作为1-精度系数),我们的框架已得到充分保证。对于基于2 x 2的收发器,估计误差值(EEV)<= 0.5的相对值几乎为10%,对于对于4 x 4的EEVs <= 0.9而言,相对误差明显增强了近5%。对于高功率方案,对于EEV <= 0.3的情况,该方案基本上保证了保密中断概率(SOP)小于0.05%。
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