Ahmet Sacid Sümer, Mehmet Mert Şahin, Hüseyin Arslan
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Concurrently, the BS utilizes Spatial\nDivision Multiple Access (SDMA) to transmit private streams to the BUs,\nresulting in BUs experiencing residual interference from the common stream\ntransmitted from relay. Incorporating this residual common stream interference\ninto our model results in a significant enhancement of the overall sum-rate\nachieved at the BUs. We derive a tractable lower bound on the ergodic\nsum-rates, enables us to develop closed-form solutions for power allocation\nthat maximize the overall sum-rate in both phases. Extensive simulations\nvalidate that our proposed power allocation algorithm, in conjunction with a\nlow-complexity precoder, significantly improves the sum-rate performance of DF\nrelay RSMA networks compared to the SDMA-based benchmark designs under\nimperfect CSI at the transmitter and relay.","PeriodicalId":501034,"journal":{"name":"arXiv - EE - Signal Processing","volume":"47 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"An Efficient Low-Complexity RSMA Scheme for Multi-User Decode-and-Forward Relay Systems\",\"authors\":\"Ahmet Sacid Sümer, Mehmet Mert Şahin, Hüseyin Arslan\",\"doi\":\"arxiv-2409.08880\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Rate-Splitting Multiple Access (RSMA) is a promising strategy for ensuring\\nrobust transmission in multi-antenna wireless systems. 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引用次数: 0
摘要
速率分割多路访问(RSMA)是确保多天线无线系统中稳健传输的一种有前途的策略。在本文中,我们研究了 RSMA 在下行链路解码前向(DF)中继场景下的性能,该场景分为两个阶段,发射机和中继站的信道状态信息(CSI)均不完善。具体来说,在第一阶段,基站(BS)首先向 BS 用户(BU)和中继发送信息。在第二阶段,中继解码并将接收到的信号转发给基站覆盖区域外的中继用户(RU)。此外,我们还研究了一种情况,即中继在第二阶段为 RU 广播一个公共流。由于传输的广播性质,RU 和 BU 都会无意中接收到该数据流。与此同时,BS 利用空间分割多路访问 (SDMA) 向 BU 传输专用流,导致 BU 受到中继传输的公共流的残余干扰。将这种残余公共流干扰纳入我们的模型,可显著提高 BU 达到的总和速率。我们推导出了一个可控的遍历总和率下限,使我们能够开发出功率分配的闭式解决方案,最大限度地提高两个阶段的总和率。大量仿真验证了我们提出的功率分配算法与低复杂度前置编码器相结合,与基于 SDMA 的基准设计相比,在发射端和中继端 CSI 不完美的情况下,能显著提高 DFrelay RSMA 网络的总和速率性能。
An Efficient Low-Complexity RSMA Scheme for Multi-User Decode-and-Forward Relay Systems
Rate-Splitting Multiple Access (RSMA) is a promising strategy for ensuring
robust transmission in multi-antenna wireless systems. In this paper, we
investigate the performance of RSMA in a downlink Decode-and-Forward (DF) relay
scenario under two phases with imperfect Channel State Information (CSI) at the
transmitter and the relay. In particular, in the first phase, the Base Station
(BS) initially transmits to both BS Users (BUs) and the relay. In the second
phase, the relay decodes and forwards the received signals to Relay Users (RUs)
outside the BS coverage area. Furthermore, we investigate a scenario where the
relay broadcasts a common stream intended for the RUs in the second phase. Due
to the broadcast nature of the transmission, this stream is inadvertently
received by both the RUs and the BUs. Concurrently, the BS utilizes Spatial
Division Multiple Access (SDMA) to transmit private streams to the BUs,
resulting in BUs experiencing residual interference from the common stream
transmitted from relay. Incorporating this residual common stream interference
into our model results in a significant enhancement of the overall sum-rate
achieved at the BUs. We derive a tractable lower bound on the ergodic
sum-rates, enables us to develop closed-form solutions for power allocation
that maximize the overall sum-rate in both phases. Extensive simulations
validate that our proposed power allocation algorithm, in conjunction with a
low-complexity precoder, significantly improves the sum-rate performance of DF
relay RSMA networks compared to the SDMA-based benchmark designs under
imperfect CSI at the transmitter and relay.