The use of a large excess of service antennas brings a variety of performance benefits to distributed MIMO C-RAN, but the corresponding high fronthaul data loads can be problematic in practical systems with limited fronthaul capacity. In this work we propose the use of lossy dimension reduction, applied locally at each remote radio head (RRH), to reduce this fronthaul traffic. We first consider the uplink, and the case where each RRH applies a linear dimension reduction filter to its multi-antenna received signal vector. It is shown that under a joint mutual information criteria, the optimal dimension reduction filters are given by a variant of the conditional Karhunen-Loeve transform, with a stationary point found using block co-ordinate ascent. These filters are then modified such that each RRH can calculate its own dimension reduction filter in a decentralised manner, using knowledge only of its own instantaneous channel and network slow fading coefficients. We then show that in TDD systems these dimension reduction filters can be re-used as part of a two-stage reduced dimension downlink precoding scheme. Analysis and numerical results demonstrate that the proposed approach can significantly reduce both uplink and downlink fronthaul traffic whilst incurring very little loss in MIMO performance.
翻译:使用大量的超量服务天线给分布式MIMIM C-RAN带来各种各样的性能效益,但相应的前方高载数据负荷在前方容量有限的实际系统中可能存在问题。在这项工作中,我们提议使用在本地对每个遥控无线电头(RRH)应用的减少损失尺寸的方法,以减少前方流量。我们首先考虑上行连接,以及每个RRRH对它接收的多屏障接收信号矢量对其多维内纳接收信号矢量应用线性降低维度过滤器的情况。我们然后表明,在联合信息标准下方,通过有条件的Karhunen-Loeve变换卡胡宁-Loeve来提供最佳的减少尺寸过滤器,并使用区块坐标坐标坐标坐标的固定点。这些过滤器随后进行了修改,这样每个RRRHW都能够以分散的方式计算其自己的减少尺寸过滤器。我们首先考虑的是,每个RRHW对它自己的瞬时通道和网络缓慢的消减度系数的知识。我们然后表明,在TDD系统中,这些减少尺寸过滤器可以被重新使用,作为分两阶段降低的下端连接前方连接计划的一部分的一部分。分析和数字结果表明,在MIMUMV中,在前端连接中几乎没有的运行中几乎没有的减少性能。