跳到主要內容

簡易檢索 / 詳目顯示

回結果列表
研究生: 洪培文
Pei-wen Hung
論文名稱: 以最大概似法之智慧型中繼策略用於多輸入輸出中繼站網路
ML-based Intelligent Relaying Strategy for MIMO Relay Networks
指導教授: 張大中
Dah-chung Chang
口試委員:
學位類別: 碩士
Master
系所名稱: 資訊電機學院 - 通訊工程學系
Department of Communication Engineering
論文出版年: 2013
畢業學年度: 101
語文別: 中文
論文頁數: 79
中文關鍵詞: 中繼網路放大並傳輸策略解碼並傳輸策略合作式通訊
外文關鍵詞: relay network, Amplify-and-forward strategy, Decode-and-forward strategy, Cooperative communication
相關次數: 點閱:12下載:0
分享至:
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報

    • 在現有的無線通訊系統中,使用中繼站 (Relay) 以增加
    傳輸的效能和訊號傳輸範圍已是未來的趨勢,在現有的中繼站傳輸策略中,較常見的有放大後傳輸 (Amplify-and-Forward,AF),即在中繼站將接收訊號放大後傳輸,與解調後傳輸 (Decode-and-Forward,DF),即在中繼站將接收訊號做解調之後再放大傳輸。但兩種策略有各自的優缺點,AF 對通道增益的影響較敏感,而 DF 需要在中繼站接收到可靠的訊號。本篇提出以最大概似比 (MaximumLikelihood,ML) 為偵測訊號的 MIMO 模型,在兩種傳輸策略中做決策,選擇要用何種方式傳輸,分析 BPSK、QPSK、16QAM 三種調變方式的錯誤率後,利用切爾諾夫邊界 (Chernoff bound) 取上界算出平均錯誤率 (Average Error Probability),以簡易的判斷式做決策。一方面降低回傳通道資訊 (Channel State Information,CSI) 的即時性,一方面提出將既有傳輸方式最佳化的策略。

    Using relays to improve the performance and extend cover-
    age area is the future trend in modern wireless transmission systems.Amplify-and-Forward (AF) and Decode-and-Forward (DF) are the most popular strategies discussed for relay transmission. AF and DF have their specific disadvantages, e.g. AF is sensitive to channel gains while DF requires reliable received signals. This thesis proposes to make decision between two transmission strategies for relay based on the ML-based MIMO transmission model. To find an intelligent strategy, we analyze three modulation types, including BPSK, QPSK and 16-QAM, and make
    decision rely on the average error probability obtained by the Chernoff
    bound. The proposed decision strategy does not need the Channel State Information(CSI) in time for reaching optimum performance.

    中文摘要.....................................i 英文摘要.....................................iii 目錄.....................................i 圖目錄.....................................iii 表目錄 .....................................iv 第 1 章序論.....................................1 1.1 前言.....................................1 1.2 章節架構.....................................4 第 2 章Relay 用於 MIMO 傳輸系統架構.....................................5 2.1 系統架構.....................................5 2.2 Relay 端傳輸策略 1:AF.....................................8 2.3 Relay 端傳輸策略 2:DF.....................................10 2.4 小結.....................................12 第 3 章Relay 端使用策略之決策法.....................................14 3.1 Amplify-and-Forward(AF) 錯誤率.....................................14 3.1.1 AF 在 BPSK 調變之位元錯誤率.....................................14 3.1.2 AF 在 QPSK 調變之符元錯誤率.....................................15 3.1.3 AF 在 16-QAM 調變之符元錯誤率.....................................16 3.2 Decode-and-Forward(DF) 錯誤率.....................................17 3.2.1 DF 在 BPSK 調變之位元錯誤率.....................................17 3.2.2 DF 在 QPSK 調變之符元錯誤率.....................................19 3.2.3 DF 在 16-QAM 調變之符元錯誤率.....................................20 3.3 上界逼近值 (upper bound) 與機率分布介紹.....................................21 3.3.1 平均錯誤率.....................................21 3.3.2 上界逼近值-切爾諾夫邊界 (Chernoff bound).....................................22 3.3.3 機率分布變化.....................................24 3.4 平均錯誤率計算.....................................27 3.4.1 AF 在 BPSK 調變之平均位元錯誤率上界.....................................27 3.4.2 AF 在 QPSK 調變之平均符元錯誤率上界.....................................28 3.4.3 AF 在 16-QAM 調變之平均符元錯誤率上界.....................................29 3.4.4 DF 在 BPSK 調變之平均位元錯誤率上界.....................................29 3.4.5 DF 在 QPSK 調變之平均符元錯誤率上界.....................................31 3.4.6 DF 在 16-QAM 調變之平均符元錯誤率上界.....................................32 3.5 考慮直線通道的錯誤率計算.....................................34 3.5.1 考慮直線通道之 AF 和 DF 錯誤率.....................................34 3.5.2 考慮直線通道之 AF 和 DF 平均錯誤率.....................................36 3.6 使用平均錯誤率決策 (Desicion).....................................39 第 4 章系統模擬與結果分析.....................................40 4.1 系統模擬參數.....................................41 4.2 BPSK 之位元錯誤率模擬.....................................41 4.2.1 通道增益比較.....................................42 4.2.2 放大係數比較.....................................47 4.2.3 exact value 與 upper bound 的平均錯誤率比較.....................................49 4.2.4 使用迴旋編碼 (Convolutional code) 傳輸.....................................51 4.2.5 合作式傳輸.....................................54 4.3 QPSK 之符元錯誤率模擬.....................................58 4.4 16-QAM 之符元錯誤率模擬.....................................62 第 5 章結論.....................................65 參考文獻 .....................................66

    [1] B. Rankov and A. Wittneben, “Spectral efficient protocols for half-duplex fading relay channels,”IEEE Journal on Selected Areas inCommunications, vol. 25, no. 2, pp. 379–389, 2007.
    [2] W. Su and X. Liu, “On optimum selection relaying protocols in cooperative wireless networks,”IEEE Transactions on Communications, vol. 58, no. 1, pp. 52–57, 2010.
    [3] Y. Liu, P. Dharmawansa, M. McKay, and K. Letaief, “Finite-snr diversity-multiplexing trade-off of dual hop multiple-relay channels,”IEEE Transactions on Communications, vol. 60, no. 5, pp.
    1451–1463, 2012.
    [4] X. Jin, J.-S. No, and D.-J. Shin, “Source transmit antenna selection for mimo decode-and-forward relay networks,”IEEE Transactions on Signal Processing, vol. 61, no. 7, pp. 1657–1662, 2013.
    [5] P. Ubaidulla and A. Chockalingam, “Relay precoder optimization in mimo-relay networks with imperfect csi,”IEEE Transactions on Signal Processing, vol. 59, no. 11, pp. 5473–5484, 2011.
    [6] S. Zhang, S. chang Liew, and P. P. Lam, “Physical-layer network coding,”in in ACM Mobicom ‘06, 2006.
    [7] M. Wilson, K. Narayanan, H. Pfister, and A. Sprintson, “Joint physical layer coding and network coding for bidirectional relaying,”IEEE Transactions on Information Theory, vol. 56, no. 11, pp.5641–5654, 2010.
    [8] G. Li, Y. Wang, and P. Zhang, “Linear mmse processing design for 3-phase two-way cooperative mimo relay systems,”IEEE Signal Processing Letters, vol. 19, no. 7, pp. 443–446, 2012.
    [9] R. Wang and M. Tao, “Joint source and relay precoding designs for mimo two-way relaying based on mse criterion,”IEEE Transactions on Signal Processing, vol. 60, no. 3, pp. 1352–1365, 2012.
    [10] E. Chiu and V. Lau, “Cellular multiuser two-way mimo af relaying via signal space alignment: Minimum weighted sinr maximization,”IEEE Transactions on Signal Processing, vol. 60, no. 9, pp.4864–4873, 2012.
    [11] Q. Liu, W. Zhang, X. Ma, and G. Zhou, “Designing peak power constrained amplify-and-forward relay networks with cooperative diversity,”IEEE Transactions on Wireless Communications, vol. 11,no. 5, pp. 1733–1743, 2012.
    [12] S. Soliman and N. Beaulieu, “Exact analysis of dual-hop af maximum end-to-end snr relay selection,”IEEE Transactions on Communications,, vol. 60, no. 8, pp. 2135–2145, 2012.
    [13] J.-B. Kim and D. Kim, “Performance of dual-hop amplify-and-forward beamforming and its equivalent systems in rayleigh fading channels,”IEEE Transactions on Communications, vol. 58, no. 3, pp. 729–732, 2010.
    [14] G. Choi, W. Zhang, and X. Ma, “Achieving joint diversity in decode-and-forward mimo relay networks with zero-forcing equalizers,”IEEE Transactions on Communications,, vol. 60, no. 6, pp.1545–1554, 2012.
    [15] G. V. V. Sharma, V. Ganwani, U. Desai, and S. Merchant, “Performance analysis of maximum likelihood detection for decode and forward mimo relay channels in rayleigh fading,”IEEE Transactions on Wireless Communications, vol. 9, no. 9, pp. 2880–2889, 2010.
    [16] C. De and S. Kundu, “Hybrid forwarding for serial and parallel wireless relaying in m-nakagami fading channel,”in 2011 2nd International Conference on Computer and Communication Technology(ICCCT),, 2011, pp. 601–606.
    [17] E. Chiu, V. Lau, S. Zhang, and B. Mok, “Precoder design for multi-antenna partial decode-and-forward (pdf) cooperative systems with statistical csit and mmse-sic receivers,”IEEE Transactions on Wireless Communications, vol. 11, no. 4, pp. 1343–1349, 2012.
    [18] M. Hasna and M.-S. Alouini, “End-to-end performance of transmission systems with relays over rayleigh-fading channels,”Wireless Communications, IEEE Transactions on, vol. 2, no. 6, pp. 1126–1131, 2003.
    [19] M. Khandaker and Y. Rong, “Interference mimo relay channel: Joint power control and transceiver-relay beamforming,”IEEE Transactions on Signal Processing, vol. 60, no. 12, pp. 6509–6518,2012.
    [20] P. Clarke and R. De Lamare, “Transmit diversity and relay selection algorithms for multirelay cooperative mimo systems,”IEEE Transactions on Vehicular Technology,, vol. 61, no. 3, pp. 1084–1098,2012.
    [21] J.G.Proakis, Digital Communications, 4th edition, Ed. McGraw-Hill, 2001.
    [22] I. Gradshteyn and I. Ryzhik, Table of Integrals, Series, and Products, 7th edition, Ed. Academic Press, 2007, p.341.
    [23] T. Wang, G. Giannakis, and R. Wang, “Smart regenerative relays for link-adaptive cooperative communications,”IEEE Transactions on Communications, vol. 56, no. 11, pp. 1950–1960, 2008.

    QR CODE
    :::