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引用次数: 8
摘要
我们考虑高斯脏带信道(DTC) Y = X + S + Z,其中S是发射机已知的加性高斯干扰。一般表达式maxPU, f(·),X = f(U, S) I(U;Y)表示该信道的容量。对于f(·)的线性赋值,即X = U - βS,该表达式导致先前Willems提出的补偿策略,以获得DTC的可实现速率。在存在一个实数β∗使得(X + β S, U)对与干扰S无关的情况下,我们证明了对f(·)的线性分配是最优的。此外,通过对由f(·)线性分配得到的可达速率应用一种时间共享技术,得到了改进的DTC容量下界。我们还考虑了具有加性干扰的高斯多址信道,并研究了该系统的两种不同情况。在第一种情况下,两个发射机都知道干扰是因果关系,而在第二种情况下,一个发射机接触到干扰是非因果关系,而另一个发射机接触到干扰是因果关系。然后建立这两个场景的可实现速率区域。
Achievable rate regions for Dirty Tape Channels and “joint writing on Dirty paper and Dirty Tape”
We consider the Gaussian Dirty Tape Channel (DTC) Y = X + S + Z, where S is an additive Gaussian interference known causally to the transmitter. The general expression maxPU, f(·), X = f(U, S) I(U; Y) is proposed for the capacity of this channel. For linear assignment to f(·), i.e., X = U — βS, this expression leads to the compensation strategy proposed previously by Willems to obtain an achievable rate for the DTC. We show that linear assignment to f(·) is optimal under the condition that there exists a real number β∗ such that the pair (X + β S, U) is independent of the interference S. Furthermore, by applying a time-sharing technique to the achievable rate derived by linear assignment to f (·), an improved lower bound on the capacity of DTC is obtained. We also consider the Gaussian multiple access channel with additive interference, and study two different scenarios for this system. In the first case, both transmitters know interference causally while in the second, one transmitter has access to the interference noncausally and the other causally. Achievable rate regions for these two scenarios are then established.
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