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引用次数: 22
摘要
我们评估了高斯n中继菱形网络上量化映射前向(QMF)中继方案的信息论可实现速率。专注于继电器上的矢量高斯量化,我们的目标是了解这些方案在菱形网络环境下与切割集上界的接近程度,以及通过优化继电器上的量化器失真获得多少好处。首先,通过噪声级量化,我们指出截止集上界的最坏情况间隙为(N + log2 N) bits/s/Hz。在不使用信道状态信息(CSI)的情况下,发现了一个更好的通用量化水平,导致log2 N + log2(1 + N) + N log2(1 + 1/N)比特/秒/Hz的间隙增大。另一方面,事实证明,在一般的n中继设置中,根据信道增益找到最佳失真电平是一个重要的问题。我们设法解析地解决了双中继问题和对称n中继问题,并通过静态和慢衰落信道的数值评估显示了改进。
Optimizing Quantize-Map-and-Forward relaying for Gaussian diamond networks
We evaluate the information-theoretic achievable rates of Quantize-Map-and-Forward (QMF) relaying schemes over Gaussian N-relay diamond networks. Focusing on vector Gaussian quantization at the relays, our goal is to understand how close to the cutset upper bound these schemes can achieve in the context of diamond networks, and how much benefit is obtained by optimizing the quantizer distortions at the relays. First, with noise-level quantization, we point out that the worst-case gap from the cutset upper bound is (N + log2 N) bits/s/Hz. A better universal quantization level found without using channel state information (CSI) leads to a sharpened gap of log2 N + log2(1 + N) + N log2(1 + 1/N) bits/s/Hz. On the other hand, it turns out that finding the optimal distortion levels depending on the channel gains is a non-trivial problem in the general N-relay setup. We manage to solve the two-relay problem and the symmetric N-relay problem analytically, and show the improvement via numerical evaluations both in static as well as slow-fading channels.
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