Jiyuan Yang, Yan Chen, Xiqi Gao, Xiang-Gen Xia, Dirk Slock
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引用次数: 0
摘要
我们提出了一种用于超大规模多输入多输出(MIMO)信号检测的群信息几何方法(GIGA)。信号检测任务的框架是计算所有用户传输数据符号后验分布的近似边际。利用近似边际值,我们执行{textsl{a posteriori}}边际值最大化(MPM)检测,以恢复每个用户的符号。基于信息几何理论和接收信号分量的分组,我们构建了三种流形,并通过 m 投影得到了近似后验边际。贝里-埃森定理的引入提供了 m 投影的近似计算,而其直接计算是指数级复杂的。在大多数情况下,组数越多,GIGA 的复杂性就越低。然而,当组数超过某个阈值时,GIGA 的复杂度就会开始增加。仿真结果证实,所提出的 GIGA 在少量迭代中就能获得较好的误码率(BER)性能,这表明它可以作为超大规模 MIMO 系统中的一种高效检测方法。
Group Information Geometry Approach for Ultra-Massive MIMO Signal Detection
We propose a group information geometry approach (GIGA) for ultra-massive
multiple-input multiple-output (MIMO) signal detection. The signal detection
task is framed as computing the approximate marginals of the a posteriori
distribution of the transmitted data symbols of all users. With the approximate
marginals, we perform the maximization of the {\textsl{a posteriori}} marginals
(MPM) detection to recover the symbol of each user. Based on the information
geometry theory and the grouping of the components of the received signal,
three types of manifolds are constructed and the approximate a posteriori
marginals are obtained through m-projections. The Berry-Esseen theorem is
introduced to offer an approximate calculation of the m-projection, while its
direct calculation is exponentially complex. In most cases, more groups, less
complexity of GIGA. However, when the number of groups exceeds a certain
threshold, the complexity of GIGA starts to increase. Simulation results
confirm that the proposed GIGA achieves better bit error rate (BER) performance
within a small number of iterations, which demonstrates that it can serve as an
efficient detection method in ultra-massive MIMO systems.
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