上行非正交多重接取窄頻物聯網系統中頻譜效率最大化之子載波分配及功率控制

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姓名

郭信宏(Shin-Horng Kuo) 查詢紙本館藏

畢業系所

通訊工程學系

論文名稱

上行非正交多重接取窄頻物聯網系統中頻譜效率最大化之子載波分配及功率控制
(Subcarrier Allocation and Power Control for Spectral Efficiency Maximization in Uplink NOMA NB-IoT Systems)

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至系統瀏覽論文 (2025-9-1以後開放)

摘要(中)

近年來，可連網裝置的數量有著爆炸性的增長。對此，窄頻物聯網（NB-IoT）系統及相關規格應運而生。本篇論文將上行窄頻物聯網系統和非正交多重接取（NOMA）系統結合，並利用一套有效的資源分配演算法，進一步提升頻譜效率和同時可服務裝置的數量。本篇論文著重在頻段內（in-band）的部署模式，並與獨立（stand-alone）模式比較。由於頻譜洩漏，除了使用同一個子載波資源的兩個裝置會互相干擾外，不同子載波內的裝置也會互相干擾。而因為頻段內模式的窄頻物聯網系統是佔用一個長期演進技術（LTE）系統的一個實體資源區塊（PRB），因此窄頻物聯網系統和長期演進技術系統的訊號也會互相干擾。本論文的演算法分為兩個部分，分別是子載波分配及傳送功率控制。將模擬結果和現存之正交多重接取（OMA）窄頻物聯網系統比較，顯示窄頻物聯網系統在結合非正交多重接取系統後，頻譜效率有顯著的提升。

摘要(英)

In recent years, there is a rapid increase in the number of network-connectable devices. In this regard, Narrowband Interference of Things (NB-IoT) systems and their specifications are developed. For improving the spectral efficiency and servicing more devices, we combine uplink NB-IoT systems and Non-Orthogonal Multiple Access (NOMA) systems with efficient resource allocation algorithms. In this thesis, we focus on the systems deployed as the in-band mode, then compare the results with the stand-alone mode. Due to spectral leakage, besides the mutual interference between two devices using the same subcarrier, the interference among different subcarriers exists as well. Furthermore, the signals from NB-IoT systems and Long-Term Evolution (LTE) systems would interfere to each other since NB-IoT systems occupy one LTE physical resource block (PRB) in the in-band mode. Our algorithm in this thesis contains two parts. The first part is to allocate subcarriers to UEs with maximum transmit power. The power control in the second part is implemented according to the subcarrier allocation result from the first part. Simulation results by comparison to the Orthogonal Multiple Access (OMA) NB-IoT systems show that the spectral efficiency is improved significantly in the proposed uplink NOMA NB-IoT systems.

關鍵字(中)

★ 窄頻物聯網
★ 非正交多重接取
★ 子載波分配
★ 功率控制

關鍵字(英)

★ Narrowband Internet of Things (NB-IoT)
★ Non-Orthogonal Multiple Access (NOMA)
★ subcarrier allocation
★ power control

論文目次

論文摘要 i
Abstract ii
致謝 iv
Contents v
List of Figures vii
List of Tables viii
Chapter1. Introduction - 1 -
1.1. NB-IoT - 1 -
1.2. NOMA - 3 -
1.3. Review of Literature - 4 -
1.4. Organization - 5 -
1.5. List of Abbreviations - 5 -
1.6. Notation - 6 -
Chapter2. System Model and Problem Formulation - 9 -
2.1. System Model - 9 -
2.2. Problem Formulation - 12 -
Chapter3. Subcarrier Allocation and Power Control - 14 -
3.1. Subcarrier Allocation - 15 -
3.1.1. User Equipment Selection - 15 -
3.1.2. Subcarrier Allocation - 17 -
3.2. Power Control - 19 -
Chapter4. Complexity Analysis - 24 -
Chapter5. Simulation Model and Results - 24 -
5.1. Simulation Model - 24 -
5.2. Simulation Results - 27 -
Chapter6. Conclusion - 32 -
Reference - 33 -

參考文獻

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指導教授

陳永芳(Yung-Fang Chen)

審核日期

2020-8-18

推文