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研究生:許文耀
研究生(外文):Wen-Yao Hsu
論文名稱:用於相差位元交錯編碼調變的碼搜尋
論文名稱(外文):Code Searches for Differential BICM
指導教授:魏瑞益
指導教授(外文):Ruey-Yi Wei
學位類別:碩士
校院名稱:國立中央大學
系所名稱:通訊工程學系
學門:工程學門
學類:電資工程學類
論文種類:學術論文
論文出版年:2015
畢業學年度:103
語文別:中文
論文頁數:88
中文關鍵詞:位元交錯編碼調變前導符號相差編碼延遲處理器籬柵編碼調變
外文關鍵詞:Bit-interleaved Coded ModulationPilot symbolsDifferential encodingDelay processorTrellis-coded modulation
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  • 被引用被引用:0
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  • 下載下載:12
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位元交錯編碼調變是適合連續衰退通道的通道碼。而
位元交錯編碼調變則可以避免因前導符號所導致的速率損失。然而,位元交錯編碼調變所使用的相差編碼是針對沒有通道碼所設計的傳統相差編碼。

在本篇論文裡,針對使用遞迴解碼的位元交錯編碼調變,我們提出一個相差編碼的最佳化演算法,並且用它來尋找使用16APSK的相差編碼。此外,針對所提出的相差編碼我們還做迴旋碼之搜尋。由模擬結果顯示,新相差編碼比起傳統相差編碼有更好的錯誤效能,並且找到可以更加改善錯誤效能的新迴旋碼。

另一方面,使用延遲處理器的籬柵編碼調變是一個具有大的最小歐式距離的編碼調變。在本篇論文中,我們也考慮用於使用延遲處理器的籬柵編碼調變的相差編碼。針對8PSK和 16APSK我們也做迴旋碼搜尋,由模擬結果可以顯示我們所提出架構的優點。

Bit-interleaved Coded Modulation (BICM) with iterative decoding (BICM-ID) are suitable for continuous fading channels. In addition, BICM-ID using differential encoding can avoid the rate loss due to pilot symbols. Conventional differential encoding for uncoded modulation was used for BICM-ID.
In this thesis, we propose a new algorithm to optimize differential encoding for BICM-ID, and use it to find the differential encoding of 16APSK (amplitude and phase-shift keying). Besides, searches of the convolutional code for the proposed differential encoding are performed. Simulation results show that the proposed differential encoding has better error performance than conventional differential encoding, and the searched new convolutional codes can further improve error performance.
On the other hand, Trellis-coded modulation using a delay processor (TCM-DP) is a coded modulation with a large minimum Euclidean distance. In this thesis, we also consider differential encoding for TCM-DP. Code searches for 8PSK (phase-shift keying) and 16APSK are done and simulation are given to show the advantage of the proposed scheme.

目錄
摘要..........................................................I
Abstract...................................................II
誌謝......................................................III
目錄.......................................................VI
圖表目錄.........................................................VIII
第一章 緒論...................................................1
1.1研究動機............................................1
1.2內容介紹............................................3
第二章 相差位元交錯編碼調變..............................4
2.1回顧位元交錯編碼調變.........................4
2.1.1迴旋碼基本架構..............................4
2.1.2位元交錯編碼調變系統架構..................7
2.2回顧使用16APSK之相差位元交錯編碼調變...8
2.2.1系統架構................................................8
2.2.2軟式回授之遞迴解碼..............................10
2.2.3學長碩士論文[9]的作法..........................15
2.3用於BICM-ID的新相差編碼...................21
2.4相差位元交錯編碼調變的碼搜尋..................24
2.5模擬結果......................................25
第三章 結合相差編碼與延遲處理器之籬柵編碼調變..........................28
3.1回顧相差籬柵編碼調變...................................28
3.1.1籬柵編碼調變.......................................28
3.1.2相差籬柵編碼調變.................................29
3.1.2.1 相差籬柵編碼定義..................................29
3.1.2.2 相差籬柵編碼調變的籬柵圖.................31
3.2 回顧具延遲處理器的籬柵編碼調變...........................32
3.3具延遲處理器的相差編碼的籬柵編碼調變.................39
3.3.1 使用 8PSK 訊號........................................39
3.3.2 使用16APSK訊號...................................43
3.4具延遲處理器的相差籬柵編碼調變...............................48
3.5以電腦搜尋最佳籬柵碼................................................51
3.5.1具延遲處理器的相差籬柵編碼調變碼搜尋....51
3.5.1.1使用8PSK訊號........................51
3.5.1.2使用16APSK訊號....................54
3.6模擬結果..........................................................56
3.6.1使用8PSK訊號...................................56
3.6.2使用16APSK訊號...............................63
第四章 結論.............................................................70
參考文獻....................................................................71

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[9] C. H. Lin, “Differential encoding for bit-interleaved coded 16APSK,
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