NB-IOT中動態頻段選擇之研究

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姓名

李育良(Yu-Liang Li) 查詢紙本館藏

畢業系所

通訊工程學系

論文名稱

NB-IOT中動態頻段選擇之研究
(The Study of Dynamic Band Selection Scheme in NB-IOT)

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摘要(中)

隨著物聯網技術的快速發展以及智能裝置大量的被使用，物與物互相彼此的連接，日後邁向萬物互聯是必然的結果，而NB-IOT在這當中扮演相當重要一環，它是技術更迭和市場需求的綜合產物，在未來的市場一致的被看好。
NB-IOT是由3GPP在Rel-13上所提出，有著覆蓋範圍廣、連接多、成本低、功耗低等眾多優點，並能使用授權頻譜，較不易受到干擾，並支援帶內、保護帶或獨立頻帶，由於NB-IOT希望能達到的其中一項目標是可以大量的連接物聯網的裝置，因此如何有效的分配這些設備進入不同的頻段是本論文要探討的，在本論文中提出AHP頻段選擇演算法來選擇較為適合的頻段給裝置，該演算法在選擇頻段時不但會考慮裝置對於每個頻段的通道品質量測參數，也會依據頻段內的負載狀況來作選擇，最後模擬的結果將顯示相較於其他方法本論文所提出的方法擁有較好的吞吐量。

摘要(英)

With the rapid development of Internet of Things and the large number of intelligent devices are used, devices and devices connected with each other. In the future, Each devices will connected is the inevitable result. NB-IOT play a very important part of this. It is by technology change and market demand synthesis product and the market consider it have a bright future.
NB-IOT is proposed by 3GPP in Rel-13 and has many advantages. Such as wide coverage, low cost, low power consumption and can use authorized spectrum. It has less interference, and support in-band, guard-band, and stand-alone. Because NB-IOT hope to achieve one of the objectives is a large number of devices can be connected. So how to effectively allocate these devices into different frequency bands is to research in this paper. In this paper proposed AHP band selection algorithm to select a more appropriate frequency band to the device. The algorithm in the choice of frequency band will not only consider the device for each band of channel quality measurement parameters, but also choose the situation in band. The final simulation results will show a better throughput tan the other methods proposed.

關鍵字(中)

★ NB-IOT
★ AHP
★ 頻段選擇

關鍵字(英)

★ NB-IOT
★ AHP
★ Band Selection

論文目次

中文摘要........................................I
英文摘要........................................II
致謝........................................... III
目錄........................................... Ⅳ
圖目錄..........................................VI
表目錄..........................................VII
第一章序論....................................1
1-1 前言....................................1
1-2 研究動機................................2
1-3 論文架構................................3
第二章相關研究背景............................4
2-1 NB-IOT介紹..............................4
2-2 NB-IOT實體層……..........................9
2-3 頻段選擇演算法…………………………................14
2-4 Jain公平性指標……........................16
第三章系統情境與架構..........................17
3-1 頻段選擇之情境..........................17
3-2 系統的架構及流程........................18
3-3 動態頻段選擇演算法-AHP演算法.............20
第四章模擬與分析..............................30
4-1 模擬之參數….............................30
4-2 模擬結果與分析...........................31
第五章結論與未來研究之方向.....................37
參考文獻........................................38

參考文獻

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[2] Huawei, “NB-IOT White Paper”, 2015.

[3]魏嘉宏，汪海瀚，”低功耗物聯網刷新架構 NB-IOT三大模式面面俱到”，2016年8月。

[4] J.Schkienz, D.Raddino “Narrowband Internet of Things Whitepaper”, IEEE Microwave Magazine, Vol. 8, no. 1, pp. 76-82, August. 2016.

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[21] Rapeepat Ratasuk, Nitin Mangalvedhe, Jorma Kaikkonen and Michel Robert, “Data Channel Design and Performance for LTE Narrowband IoT”, 2016 IEEE International Conference, pp. 1-5.

指導教授

吳中實(Jung-Shyr Wu)

審核日期

2017-7-24

推文