Full-Duplex Transceiver for Future Cellular Network: A Smart Antenna Approach

TL;DR

This paper introduces a full-duplex transceiver architecture for cellular networks that employs smart antennas, SVD, and SSIC-OO algorithms to enable simultaneous uplink and downlink communication on the same subcarriers, significantly enhancing spectrum efficiency.

Contribution

It proposes a novel full-duplex transceiver design with smart antenna techniques and advanced signal processing to improve spectrum utilization in future cellular networks.

Findings

Significant increase in spectrum efficiency per cell.

Effective interference mitigation using smart antennas.

Successful implementation of simultaneous uplink and downlink on same subcarriers.

Abstract

In this paper, we propose a transceiver architecture for full-duplex (FD) eNodeB (eNB) and FD user equipment (UE) transceiver. For FD communication,.i.e., simultaneous in-band uplink and downlink operation, same subcarriers can be allocated to UE in both uplink and downlink. Hence, contrary to traditional LTE, we propose using single-carrier frequency division multiple accesses (SC-FDMA) for downlink along with the conventional method of using it for uplink. The use of multiple antennas at eNB and singular value decomposition (SVD) in the downlink allows multiple users (MU) to operate on the same set of ubcarriers. In the uplink, successive interference cancellation with optimal ordering (SSIC-OO) algorithm is used to decouple signals of UEs operating in the same set of subcarriers. A smart antenna approach is adopted which prevents interference, in downlink of a UE, from uplink signals of other UEs sharing same subcarriers. The approach includes using multiple antennas at UEs to form directed beams towards eNode and nulls towards other UEs. The proposed architecture results in significant improvement of the overall spectrum efficiency per cell of the cellular network.