This paper gives the long sought network version of water-filling named as polite water-filling.Unlike in single-user MIMO channels, where no one uses general purpose optimization algorithms in place of the simple and optimal water-filling for transmitter optimization, the traditional water-filling is generally far from optimal in networks as simple as MIMO multiaccess channels (MAC) and broadcast channels (BC), where steepest ascent algorithms have been used except for the sum-rate optimization. This is changed by the polite water-filling that is optimal for all boundary points of the capacity regions of MAC and BC and for all boundary points of a set of achievable regions of a more general class of MIMO B-MAC interference networks, which is a combination of multiple interfering broadcast channels, from the transmitter point of view, and multiaccess channels, from the receiver point of view, including MAC, BC, interference channels, X networks, and most practical wireless networks as special case. It is polite because it strikes an optimal balance between reducing interference to others and maximizing a link's own rate. Employing it, the related optimizations can be vastly simplified by taking advantage of the structure of the problems. Deeply connected to the polite water-filling, the rate duality is extended to the forward and reverse links of the B-MAC networks. As a demonstration, weighted sum-rate maximization algorithms based on polite water-filling and duality with superior performance and low complexity are designed for B-MAC networks and are analyzed for Interference Tree (iTree) Networks, a sub-class of the B-MAC networks that possesses promising properties for further information theoretic study. 5 interpretation.Directly applying single-user water-filling to networks is referred to as selfish water-filling here. It is well known to be far from optimal [26]-[28] because it does not control interference to others. Based on selfish water-filling, game-theoretic, distributed, and iterative algorithms have been well studied for DSL [26], [29]-[33], for MIMO interference channels, e.g., [34]-[37], and for multiaccess channels, e.g., [28]. The algorithms converge only under stringent conditions and the performance is not near optimal.The importance of controlling interference to others has been recognized in literature, e.g., [11],[38]- [40]. But a systematic, general, and optimal method has not been found. In interference pricing method, each user maximizes its own utility minus the interference cost determined by the interference prices. With a proper choice of the interference price which can be reverse engineered from the KKT conditions, the interference pricing based method can find a stationary point of the sum utility maximization problem. Several monotonically convergent interference pricing algorithms have been proposed in [41]-[43] for the SISO/MISO interference channels, and the MIMO interference channel with single data stream transmission. Except for the SISO case, all these algorithms update e...
