在高速鐵路環境下正交分頻多工系統使用線性通道估測及通道估測更新技術之比較與改進

Chia-Lun Hsu; 許嘉倫

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/27965

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	張進福(Jin-Fu Chang)
dc.contributor.author	Chia-Lun Hsu	en
dc.contributor.author	許嘉倫	zh_TW
dc.date.accessioned	2021-06-12T18:30:33Z	-
dc.date.available	2007-08-28
dc.date.copyright	2007-08-28
dc.date.issued	2007
dc.date.submitted	2007-08-01
dc.identifier.citation	[1] T. Maehata, M. Imai, K. Tanaka, H. Takahashi, N. Hirakata, A. Kamemura and N.Yumoto, “DSRC using OFDM for roadside-vehicle communication system”,VTC 2000-Spring Tokyo 2000 IEEE 51st Volume 1, pp. 148 – 152, 2000 [2] S. Sibecas, C. A. Corral, S. Emami and G. Stratis, “On the suitability of 802.11a/RA for high-mobility DSRC”, VTC 2002-Spring IEEE 55th Volume 1,pp. 229 – 234, 2002 [3] S. Sibecas, C. A. Corral, S. Emami, G. Stratis and G. Rasor, “Pseudo-pilot OFDM scheme for 802.11a and R/A in DSRC applications”, VTC 2003-Fall 2003 IEEE 58th Volume 2, pp. 1234 – 1237, 2003 [4] J. Irvine, J. -P. Couvy, F. Graziosi, J. Laurila, G. Mossakowski and P. Robin,“System architecture for the MOSTRAIN project (mobile services for high speedtrains)”, VTC 1997 IEEE 47th Volume 3, pp. 1917 – 1921, 1997 [5] http://www.videolan.org/streaming/ [6] Kun-De Lin and Jin-Fu Chang, “Communications and entertainment onboard a high-speed public transport system”, IEEE Wireless Communications, Volume 9, Issue 1, Feb. 2002, pp. 84 – 89, 2002 [7] G. I. Ohta, F. Kamada, N. Teramura and H. Hojo, “5 GHz W-LAN verification for public mobile applications - Internet newspaper on train and advanced ambulance car”, CCNC 2004 IEEE 1st, pp. 569 – 574, 2004 [8] Theodore S. Rappaport, “Wireless Communications: Principles and Practice”, 2nd Edition, Prentice Hall PTR, 2002 [9] M. Goller, “Application of GSM in high speed trains: measurements and simulations”, IEE Colloquium on Radiocommunications in Transportation 1995, pp. 5/1 – 5/7, 1995 [10] ETSI TR 125 943 V5.1.0 [11] http://www.thsrc.com.tw [12] P. Robertson and S. Kaiser, “Analysis of the loss of orthogonality through Doppler spread in OFDM symbols”, IEEE GLOBECOM '99 Volume 1B, pp. 701 – 706, 1999 [13] Ji-Woong Choi and Yong-Hwan Lee, “Optimum Pilot Pattern for Channel Estimation in OFDM Systems”, IEEE TRANSACTIONS ON WIRELESS COMMUNICATIONS, VOL. 4, NO. 5, SEPTEMBER 2005 [14] R. Funada, H. Harada, Y. Kamio, S. Shinoda and M. Fujise, “A high-mobility packet transmission scheme based on conventional standardized OFDM formats”, VTC 2002-Fall IEEE 56th Volume 1, pp. 204 – 208, 2002 [15] A. Dowler, A. Nix and J. McGeehan, “Data-derived iterative channel estimation with channel tracking for a mobile fourth generation wide area OFDM system”, IEEE GLOBECOM '03 Volume 2, pp. 804 – 808, 2003 [16] 彭馳, “在高速鐵路環境下使用正交分頻多工技術頁框格式之研究”, 國立台灣大學電信工程研究所, June 2005 [17] 袁文浩, “WCDMA通訊系統在超高速移動環境下的通道估測演算法之研究” , 國立台灣大學電信工程研究所, June 2006
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/27965	-
dc.description.abstract	本研究的目的在於探討“在高速鐵路環境下，提供正交分頻多工無線通訊系統有效的通道估測方式”。在高速移動環境下，由於無線通道中多重路徑干擾及都卜勒效應所產生的種種現象，使得無線通訊信號會遇到許多干擾，造成傳輸困難。雖然有直視波的存在，且郊區之延遲路徑較少可簡化問題，但	zh_TW
dc.description.abstract	This paper focuses on “effective channel estimations for OFDM wireless communication system in high speed train environment.” Because of multi-path interference and Doppler effect, wireless communication signals are interfered and hard to be transmitted. Although there are the existence of line of sight and fewer delay paths in high speed train environment to improve the situation, we still have to use more known signals to estimate the channel state correctly, which will lower the transmission efficiency. In this paper, we will discuss some methods to improve this situation. We first use traditional linear channel estimation to figure out how many known signals are in use, and how much space do we need to set for the pilots in high mobility environment. Then, we use the method of updating channel state information to achieve lower bit error rate and higher transmission efficiency in high mobility environment. In order to improve the transmission efficiency, we also try many kinds of methods to solve the problems under different situations to achieve our goal. Finally, we compare each method of channel estimation by simulation, and we propose some ways that we can further improve the system in the future.	en
dc.description.provenance	Made available in DSpace on 2021-06-12T18:30:33Z (GMT). No. of bitstreams: 1 ntu-96-R94942099-1.pdf: 2045832 bytes, checksum: c4118e5b1174c3d4e40824319e3dd850 (MD5) Previous issue date: 2007	en
dc.description.tableofcontents	目錄口試委員會審定書........................................................................................i 誌謝................................................................................................................i 中文摘要......................................................................................................iii 英文摘要.......................................................................................................v 第一章緒論.................................................................................................1 1.1 前言.................................................................................................1 1.2 研究動機.........................................................................................3 1.3 研究背景.........................................................................................3 1.4 無線連結之架構.............................................................................4 1.5 本章結論與論文架構...................................................................11 第二章高速鐵路環境對正交分頻多工系統之影響及線性通道估測之參數設計.....................................................................................................15 2.1 正交分頻多工(OFDM)系統介紹.................................................15 2.2 通道環境的介紹...........................................................................17 2.3 高速鐵路通道環境對OFDM訊號傳輸的影響............................24 2.4 高速鐵路環境下OFDM線性通道估測的調配............................27 2.5 結論...............................................................................................35 第三章通道估測更新系統在高速鐵路環境下系統效能之改進...........37 3.1 以資料驅動的方式作通道估測...................................................37 3.2 利用兩邊夾擠方式的資料反饋通道更新系統...........................46 3.3 利用高速鐵路環境特性做通道估測更新的改善.......................50 3.4 在頻域做資料反饋的通道估測更新技術...................................54 3.5 結論...............................................................................................62 第四章利用鐵路路徑已知資訊修正都卜勒偏移對傳輸效能之改進...65 4.1 行進方向夾角的討論...................................................................65 4.2 利用已知路徑補償都卜勒偏移...................................................71 4.3 對通道已知架構之實際模擬與比較...........................................72 4.4 結論...............................................................................................78 第五章結論...............................................................................................81 5.1 結論...............................................................................................81 參考文獻.....................................................................................................85 圖目錄圖1-1 系統架構............................................................................................4 圖1-2 單鏈架構示意圖................................................................................5 圖1-3 單鏈使用中繼器之架構....................................................................6 圖1-4 雙鏈使用集中器之架構....................................................................7 圖1-5 雙鏈列車使用完整基地台之架構....................................................7 圖1-6 大涵蓋範圍全向性天線的一維細胞規劃........................................9 圖1-7 小涵蓋範圍系統示意圖..................................................................10 圖1-8 整體系統架構圖..............................................................................12 圖2-1 OFDM系統方塊圖...........................................................................16 圖2-2 保護區間示意圖..............................................................................17 圖2-3 CP示意圖..........................................................................................17 圖2-4 都卜勒效應示意圖..........................................................................18 圖2-5 多重路徑干擾延遲分布圖..............................................................19 圖2-6 同步誤差與保護區間示意圖..........................................................26 圖2-7 各種不同的領航字元擺放方式......................................................29 圖2-8 高速移動環境下載波數64的線性通道估測比較圖......................32 圖2-9 高速移動環境下載波數512的線性通道估測比較圖....................33 圖2-10 高速移動環境下載波數1024的線性通道估測比較圖................33 圖2-11 高速移動環境下不同載波數的通道線性估測比較圖................34 圖3-1 以資料驅動方式作通道估測之傳送機及接收機方塊圖..............38 圖3-2 傳送資料必須先分解為數個編碼區塊..........................................40 圖3-3 載波數64之線性估測與通道估測更新在高速鐵路環境下之效能表現................................................................................................41 圖3-4 線性通道估測與通道估測更新對通道變化速度的適應力比較..42 圖3-5 載波數512之線性估測與通道估測更新在高速鐵路環境下之效能表現................................................................................................43 圖3-6 載波數512之通道估測更新在移動速度較低時之效能表現........44 圖3-7 載波數1024之線性估測與通道估測更新在高速鐵路環境下之效能表現............................................................................................45 圖3-8 通道估測更新系統之頁框格式示意圖..........................................47 圖3-9 不同頁框長度在高速移動環境下的效能表現..............................48 圖3-10 載波數512之兩邊夾擠通道估測更新在高速鐵路環境下之效能表現................................................................................................49 圖3-11 載波數1024之兩邊夾擠通道估測更新在高速鐵路環境下之效能表現................................................................................................50 圖3-12 利用高速鐵路環境特性通道估測更新系統之頁框格式示意圖....................................................................................................51 圖3-13 利用高速鐵路環境特性之通道估測更新系統的效能比較(短符碼數) ..............................................................................................52 圖3-14 利用高速鐵路環境特性之通道估測更新系統的效能比較(長符碼數) ..............................................................................................53 圖3-15 利用高速鐵路環境特性且兩邊夾擠之通道估測更新系統的效能比較................................................................................................54 圖3-16 完全追跡通道時域變化之領航字元擺放方式............................55 圖3-17 在頻率以資料驅動方式作通道估測之傳送機及接收機方塊圖....................................................................................................56 圖3-18 載波數1024之線性估測與在頻域通道估測更新在較短頁框時效能表................................................................................................58 圖3-19 載波數1024之線性估測與在頻域通道估測更新在較長頁框時效能表現............................................................................................59 圖3-20 串連加密擾亂之示意圖................................................................60 圖3-21 以新加密方式在頻域領航字元間隔較小之通道估測更新的效能表現................................................................................................61 圖3-22 以新加密方式在頻域領航字元間隔較大之通道估測更新的效能表現................................................................................................62 圖4-1 鐵路環境架構示意圖......................................................................66 圖4-2 載波數1024時域間隔1之不同行進夾角下的線性通道估測效能表現....................................................................................................67 圖4-3 載波數1024時域間隔4之不同行進夾角下的線性通道估測效能表現....................................................................................................68 圖4-4 載波數512都卜勒偏移50之不同行進夾角下的通道估測更新效能表現................................................................................................69 圖4-5 載波數1024高速移動時不同行進夾角下的通道估測更新效能表現....................................................................................................70 圖4-6 傳統接收機架構..............................................................................72 圖4-7 接收機都卜勒偏移補償架構..........................................................72 圖4-8 載波數64之直視波都卜勒偏移已知線性通道估測頻域間隔比較圖....................................................................................................73 圖4-9 載波數64之直視波都卜勒偏移已知線性通道估測時域間隔比較圖....................................................................................................74 圖4-10 載波數512之直視波都卜勒偏移已知線性通道估測時域間隔比較圖................................................................................................75 圖4-11 載波數1024之直視波都卜勒偏移已知線性通道估測時域間隔比較圖................................................................................................76 圖4-12 直視波都卜勒偏移已知通道估測更新在不同載波數之比較圖....................................................................................................77 圖4-13 直視波都卜勒偏移已知線性通道估測與通道估測更新之比較圖....................................................................................................78 表目錄表2-1 COST259的通道模型......................................................................22 表2-2 減化之COST259 RA通道模型.......................................................23 表2-3 不同載波數的領航位元適當的時間以及頻率間隔......................31
dc.language.iso	zh-TW
dc.title	在高速鐵路環境下正交分頻多工系統使用線性通道估測及通道估測更新技術之比較與改進	zh_TW
dc.title	A Study on Linear Channel Estimation and Updating Channel State Information for OFDM System in High-Speed Train Environment	en
dc.type	Thesis
dc.date.schoolyear	95-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	魏學文,鐘嘉德,黃政吉
dc.subject.keyword	多重路,徑干擾,都卜&#63826,效應,線性通道估測,通道估測更新,傳輸效率,	zh_TW
dc.subject.keyword	multi-path interference,Doppler effect,transmission efficiency,linear channel estimation,updating channel state information,	en
dc.relation.page	86
dc.rights.note	有償授權
dc.date.accepted	2007-08-02
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	電信工程學研究所	zh_TW
顯示於系所單位：	電信工程學研究所

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