Abstract
This paper studies the capacity region of a K-user cyclic Gaussian interference channel, where the kth user interferes with only the (k-1)th user (mod K ) in the network. Inspired by the work of Etkin, Tse, and Wang, who derived a capacity region outer bound for the two-user Gaussian interference channel and proved that a simple Han-Kobayashi power-splitting scheme can achieve to within one bit of the capacity region for all values of channel parameters, this paper shows that a similar strategy also achieves the capacity region of the K-user cyclic interference channel to within a constant gap in the weak interference regime. Specifically, for the K-user cyclic Gaussian interference channel, a compact representation of the Han-Kobayashi achievable rate region using Fourier-Motzkin elimination is first derived; a capacity region outer bound is then established. It is shown that the Etkin-Tse-Wang power-splitting strategy gives a constant gap of at most 2 bits in the weak interference regime. For the special three-user case, this gap can be sharpened to 1 ½ bits by time-sharing of several different strategies. The capacity result of the K-user cyclic Gaussian interference channel in the strong interference regime is also given. Further, based on the capacity results, this paper studies the generalized degrees of freedom (GDoF) of the symmetric cyclic interference channel. It is shown that the GDoF of the symmetric capacity is the same as that of the classic two-user interference channel, no matter how many users are in the network.
Highlights
The interference channel models a communication scenario where several mutually interfering transmitter-receiver pairs share the same physical medium
Instead of treating the general K-user interference channel, this paper focuses on a cyclic Gaussian interference channel model, where the kth user interferes with only the (k − 1)th user
In the two-user case, the shape of the Han-Kobayashi achievable rate region is the union of polyhedrons with boundaries defined by rate constraints on R1, R2, R1 + R2, and on 2R1 + R2 and 2R2 + R1, respectively
Summary
The interference channel models a communication scenario where several mutually interfering transmitter-receiver pairs share the same physical medium. Etkin, Tse and Wang [8] showed that the Han-Kobayashi scheme can achieve to within one bit of the capacity region for the two-user Gaussian interference channel for all channel parameters. Their key insight was that the interference-to-noise ratio (INR) of the private message should be chosen to be as close to 1 as possible in the Han-Kobayashi scheme. Practical communication systems often have more than two transmitter-receiver pairs, yet extending the one-bit result of Etkin, Tse and Wang’s work to beyond the two-user case is by no means trivial This is because when more than 2 users are involved, the Han-Kobayashi privatecommon superposition coding strategy becomes exceedingly complicated. These four types of rate constraints completely characterize the Han-Kobayashi region for the K-
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