博碩士論文 89521010 完整後設資料紀錄

DC 欄位 語言
DC.contributor電機工程學系zh_TW
DC.creator翁盟智zh_TW
DC.creatorMeng-Tzer Wongen_US
dc.date.accessioned2002-7-8T07:39:07Z
dc.date.available2002-7-8T07:39:07Z
dc.date.issued2002
dc.identifier.urihttp://ir.lib.ncu.edu.tw:444/thesis/view_etd.asp?URN=89521010
dc.contributor.department電機工程學系zh_TW
DC.description國立中央大學zh_TW
DC.descriptionNational Central Universityen_US
dc.description.abstract隨著網際網路資料傳輸速度的與日遽增,低成本高速串列式傳輸技術亦隨之蓬勃發展。串列式收發器的應用相當廣,可應用在光纖網路、萬用串列匯流排(USB)、IEEE-1394、TMDS等系統。傳統上,收發器多使用昂貴的砷化鎵製程,今日,數十億赫茲的射頻積體電路已經成功地使用深次微米CMOS和BicMOS製程實現出來。為了降低製程元件成本,本論文探討使用0.35微米矽製程來實現收發器之相關電路設計技術,其具體目的在達成每秒2.5十億位元(2.5Gbps)的串列式收發器電路。 在傳送端方面,本論文提出一個2伏、每秒2.5十億位元(2.5Gbps)的CMOS資料串列傳輸器。藉由一個低抖動和八個相位的鎖相迴路對多工器做時間區分,可將平行的資料轉換成串列的訊號。本論文提出一個可預先充電的多工器,用以減少多工器造成的抖動。 在接收端方面,本論文提出一個使用3倍超取樣技術的資料回復器,其功能是將串列的訊號轉換回平行的資料。藉由鎖相迴路和內插器產生的相位,可對串列訊號做3倍取樣,此資料回復器不僅可決定出最佳的取樣點、亦可找到資料的起始位置,還可以處理頻率偏移的問題。本論文在內插器裡用了平均的技巧,可以產生更精準的相位分佈,而在決定最佳取樣點方面,則使用電流控制數位類比轉換器(current-steering DAC)的架構來減小設計的複雜度、整體面積以及延遲的時間。 在傳送端,其最大的轉換速率超過每秒312.5百萬位元組(312.5Mbytes/s),並且可達到2.5十億位元(2.5Gbps)的傳輸速度,經量測的結果,均方根抖動小於6ps,其眼圖符合OC-48的要求,晶片面積為1062微米 * 1020微米。 在接收端,其鎖相迴路的頻率範圍可由80百萬赫茲(80MHz)至450百萬赫茲(450MHz),輸入串列訊號頻率為每秒2.5十億位元(2.5Gbps),可輸出八個每秒312.5百萬位元(312.5Mbps)的平行資料,還可處理2.5百萬赫茲(2.5MHz)的頻率偏移,整個核心電路操作在2伏電壓,而輸入及輸出的緩衝器操作在3伏電壓,所有功率消耗約280毫瓦,全部面積約2.9毫米 *2.4毫米。zh_TW
dc.description.abstractIn transmitter design, a 2V and 2.5Gbps CMOS data serializer has been proposed. High speed parallel to serial data conversion is achieved by means of time-division multiplexer toggled by a low jitter 8-phases phase-locked loop. This thesis proposes a precharge multiplexer to reduce jitter. At the receiver side, a 3* oversampling data recovery is described. The utility of data recovery is to convert serial signal back to parallel data. The serial signal is sampled by phases which are generated by a phase-locked loop and interpolators. This data recovery not only finds the optimal sampling points and the start of data, but also handles the problem of frequency offset. This thesis proposes the interpolators with average resistors in order to generate phases more accurately. In finding optimal sampling points, this thesis uses the architecture of current steering digital-to-analog converter. This implementation decreases the complication of circuit design, entire area, and latency. The transmitter achieves a conversion rate up to 312.5Mbyte/s and a transmission speed of 2.5Gbps. The measured RMS jitter is less than 6ps from a 2.5Gbps data output. The measured eye diagram meets OC-48 transition mask. Die size is 1062um * 1020um. In the receiver design, the frequency range of phase-locked loop is from 80MHz to 450MHz. The frequency of input serial data is 2.5Gbps, and the frequencies of output 8 parallel data are 312.5Mbps. The latency from input to output is 102.4ns. This data recovery can handle 2.5MHz frequency offset. Core circuits are operated under a 2V supply and input and output buffers are operated under a 3V supply. Total power consumption is about 280mW, and the entire area is about 2.9mm * 2.4mm.en_US
DC.subject串列zh_TW
DC.subject收發器zh_TW
DC.subject傳送器zh_TW
DC.subject接收器zh_TW
DC.subjectreceiveren_US
DC.subjecttransmitteren_US
DC.subjecttransceiveren_US
DC.subjectserial linken_US
DC.title2.5Gbps CMOS串列式傳輸收發器設計zh_TW
dc.language.isozh-TWzh-TW
DC.titleA 2.5Gbps CMOS Serial Link Transceiver Designen_US
DC.type博碩士論文zh_TW
DC.typethesisen_US
DC.publisherNational Central Universityen_US

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