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Asynchronous Transmission for Multiple Access Channels: Rate-Region Analysis and System Design for Uplink NOMA

Mehdi Ganji, Xun Zou, Hamid Jafarkhani

2021IEEE Transactions on Wireless Communications27 citationsDOIOpen Access PDF

Abstract

In this work, we thoroughly analyze the rate-region provided by the asynchronous transmission in multiple access channels (MACs). We derive the corresponding capacity-regions, applicable to a wide range of pulse shaping methods. We analytically prove that asynchronous transmission enlarges the capacity-region of MACs. Although successive interference cancellation (SIC) can achieve the optimal sum-rate for the conventional uplink non-orthogonal multiple access (NOMA) methods, it is unable to achieve the boundary of the capacity-region for the asynchronous transmission. We demonstrate that for the asynchronous transmission, the optimal SIC decoding order to achieve the maximum sum-rate is based on the users' channel strengths. This optimal ordering is in contrast to the conventional uplink NOMA, where various decoding orders can result in the maximum sum-rate. Furthermore, we provide practical transceiver designs to approach the capacity-region. The memory induced by asynchronous transmission enables the use of the trellis-based detection methods which improves the performance. In addition, we propose a transceiver design, based on channel diagonalization to exploit the frequency-selectivity introduced by timing offsets. The proposed transceiver design, joint with the turbo principle, enables us to achieve a rate pair that is not achievable by the synchronous transmission.

Topics & Concepts

Asynchronous communicationTelecommunications linkComputer scienceTransmission (telecommunications)Single antenna interference cancellationNomaDecoding methodsTransceiverChannel (broadcasting)Interference (communication)Electronic engineeringComputer networkWirelessTelecommunicationsEngineeringAdvanced Wireless Communication TechnologiesPAPR reduction in OFDMOptical Wireless Communication Technologies