Abstract
The downlink of a two-layered heterogeneous network is studied with macro basestations (MBs), small-cell basestations (SBs) that act as half-duplex analog relays, and mobile terminals (MTs). The first layer is a wireless backhaul layer between MBs and SBs, and the second is the transmission layer between SBs and MTs. The layers use the same time/frequency resources for communication, limiting the maximum per user degrees of freedom (puDoF) to half, due to the half-duplex nature of the SBs. For linear network models, it is established that the optimal puDoF can be achieved by cooperation with an appropriate number of antennas that depends on the connectivity of the network. The proposed zero-forcing schemes achieve cooperation without overloading the backhaul, through each MB sending an appropriate linear combination of MTs' message signals to the SBs in the backhaul layer. The achievable schemes exploit the half-duplexity of the SBs, and schedule the SBs and MTs to be active in different time-slots to manage interference. These results are then extended to a more realistic hexagonal cellular network and it is shown that the optimal puDoF of half can be approached using only zero-forcing schemes.
Highlights
T O MEET the increasing demand for mobile traffic, heterogeneous networks are envisioned to be a key component of future cellular networks [4]
Our main contributions are as follows: 1) We model the heterogenous network with macro basestations (MBs), small-cell basestations (SBs), and mobile terminals (MTs) as a two-layered interference network with SBs that act as half-duplex analog relays between the MBs and the MTs
We considered a heterogeneous cellular network consisting of MBs, SBs and MTs with a wireless backhaul layer, and with the SBs acting as half-duplex relays
Summary
T O MEET the increasing demand for mobile traffic, heterogeneous networks are envisioned to be a key component of future cellular networks [4]. Managing interference in such heterogeneous networks is crucial in order to achieve higher data rates for the users. We consider the downlink of a cellular network as a heterogeneous network consisting of macro basestations (MBs), small cell basestations (SBs), and the mobile terminals (MTs). We consider a linear network model first, and study the more practical hexagonal sectored cellular network with and without intra-cell interference in the transmission layer. This work was extended to the hexagonal cellular network in [12] and [13] In all these works, cooperation is achieved by making each message available at multiple transmitters and has been shown to significantly increase the achievable DoF in these networks
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