Abstract
We propose a concept system termed distributed base station (DBS) which enables distributed transmit beamforming at large carrier wavelengths to achieve significant range extension and/or increased downlink data rate, providing a low-cost infrastructure for applications such as rural broadband. We consider a frequency division duplexed (FDD) system using feedback from the receiver to achieve the required phase coherence. At a given range, N cooperating transmitters can achieve N2-fold increase in received power compared to that for a single transmitters, and feedback-based algorithms with near-ideal performance have been prototyped. In this paper, however, we identify and address key technical issues in translating such power gains into range extension via a DBS. First, to combat the drop in per-node SNR with extended range, we design a feedback-based adaptation strategy that is suitably robust to noise. Second, to utilize available system bandwidth, we extend narrowband adaptation algorithms to wideband channels through interpolation over OFDM subcarriers. Third, we observe that the feedback channel may become a bottleneck unless sophisticated distributed reception strategies are employed, but show that acceptable performance can still be obtained with standard uplink reception if channel time variations are slow enough. We quantify system performance compactly via outage capacity analyses.
Highlights
Distributed transmit beamforming with N cooperating transmitters can provide received power N2-fold larger than that of a single transmitter
While our later system-level numerical results are for a distributed base station (DBS) with 10 nodes, we consider a larger number of nodes (N = 100) in order to stress test the feedback strategies considered
The distributed base station concept presented in this paper is a promising approach for providing broadband access to remote areas, combining the benefits of massive MIMO with the superior propagation characteristics of large carrier wavelengths
Summary
Distributed transmit beamforming with N cooperating transmitters can provide received power N2-fold larger than that of a single transmitter. A DBS comprises N opportunistically placed, low-cost, transmitter nodes, without wired connections between the nodes. Our goal is to leverage the N2-fold received power gain provided by distributed transmit beamforming to significantly enhance downlink range and/or spectral efficiency. While a DBS can be employed to enhance communication in existing WiFi and LTE bands, the approach is interesting for white space frequencies (e.g., 50–800 MHz). These frequencies propagate well and are well matched to long-range applications such as rural broadband. DBS allows the use of low-cost transmit nodes with moderate transmit power to emulate a powerful transmitter with a highly directional steerable antenna
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