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姓名 張啟揚(Chi-Yang Chang)  查詢紙本館藏   畢業系所 電機工程學系
論文名稱 操作在0.5伏特下具溫度補償技術非石英振盪器之全數位式時脈產生器
(A 0.5 V All Digital Crystal-less Clock Generator with Temperature Compensation)
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摘要(中) 本論文提出一操作在0.5伏特,具溫度補償機制之非石英式時脈產生器。此架構利用溫度補償電路,針對晶片溫度改變時,將調整時脈產生器之操作頻率,校正到系統所需之操作頻率。當溫度改變時,溫度補償電路利用環形振盪器輸出頻率變化。將其輸出頻率經過時間轉數位轉換器作運算,並送入數位濾波器中,對數位控制振盪器做頻率補償。若校正頻率的幅度不足時,可以調整時間放大器的增益值,將溫度補償電路的修正幅度提高。
本論文之全數位式非石英式時脈產生器使用TSMC 65 nm 1P9M CMOS製程實現晶片,當溫度變化從0°C到100°C時,此全數位非石英式時脈產生晶片之操作頻率可達到300 MHz且操作電壓為0.5 V。其架構實現於65 nm CMOS製程下,電路面積為422×353 um2。其功率消耗為1.05 mW且操作頻率精準度達到±2%。因此,全數位非石英式時脈產生器架構將容易整合於低電壓之操作與數位系統之應用。
摘要(英) A low voltage all digital crystal-less clock generator (CLCG) is presented. All digital CLCG adopts the temperature compensation circuit to calibrate the CLCG operational frequency. The temperature compensation circuit adjusts the operational frequency of CLCG to achieve the target frequency. The temperature compensation adopts ring oscillator to detect the temperature variations. When the temperature varies, the temperature compensation circuit creates the compensation code and feeds the digital code to digital loop filter (DLF). The DLF output codes can adjust the digital control oscillator (DCO) output frequency. If the target frequency is not arrived, The timing amplifier (TA) gain can be adjusted for frequency compensation.
The experimental chip was fabricated by TSMC 65 nm 1P9M CMOS process. Under the temperature is from 0°C to 100°C, the all-digital CLCG output produces a target frequency of 300 MHz under the 0.5 V supply voltage. The core area is 422×353 um2 in a 65 nm CMOS process. The power consumption and frequency accuracy of CLCG are less than 1.05 mW and ±2%, respectively. This all digital CLCG is suitable for low supply voltage applications and digital systems.
關鍵字(中) ★ 無石英振盪器
★ 溫度
★ 時間放大器
★ 多相位
★ 數位濾波器
★ 補償
關鍵字(英) ★ Crystalless
★ Temperature
★ Timing Amplifier
★ Multi-Phase
★ Digital Loop Filter
★ Compensation
論文目次 摘 要 i
Abstract ii
誌謝 iii
目錄 iv
圖目錄 vi
表目錄 viii
第1章 緒論 1
1.1 研究動機 1
1.2 研究目的及其應用 2
1.3 論文架構 3
第2章 非石英式全數位時脈產生器技術探討 4
2.1 非石英式時脈產生器種類簡介 4
2.2 非石英式時脈產生器架構探討 6
2.2.1 溫度補償之弛張振盪器[10] 6
2.2.2 含溫度補償之非石英振盪器[11] 7
2.2.3 具LC振盪器之非石英振盪器[12] 9
2.2.4 應用於生醫系統具頻率追鎖迴路之非石英振盪器[13] 10
2.2.5 非石英式時脈產生器架構規格比較 11
2.3 本論文預計規格 12
第3章 具溫度補償機制之非石英式全數位時脈產生器 14
3.1 設計概念 14
3.2 非石英式全數位振盪器架構及操作 16
3.3 初始頻率設定 (Frequency Setting) 18
3.4 溫度漂移(Temperature Variation) 20
3.5 頻率補償(Frequency Compensation) 21
第4章 非石英式全數位時脈產生器架構分析與子電路介紹 25
4.1 多重相位數位控制振盪器 (MP-DCO) 25
4.1.1 多重相位數位控制振盪器公式探討[14] 25
4.1.2 多重相位數位控制振盪器架構[15] 28
4.1.3 多重相位數位控制振盪器模擬結果 31
4.2 時間數位轉換器(TDC) 33
4.2.1 時間數位轉換器架構 33
4.2.2 時間數位轉換器模擬結果 36
4.2.3 時間數位轉換器之位元數探討 39
4.3 時間放大器(TA) 40
4.4 非石英式全數位時脈產生器之S-domain分析 41
4.5 數位迴路濾波器[19] 42
4.5.1 計算數位迴路濾波器之參數 43
第5章 無石英式時脈產生電路模擬與 晶片量測結果 47
5.1 設計流程 47
5.2 電路模擬 47
5.3 電路佈局 50
5.4 晶片照相與量測環境設定 51
5.5 量測結果 53
5.6 規格比較 59
第6章 結論與未來研究方向 61
6.1 結論 61
6.2 未來研究方向 62
參考文獻 63
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指導教授 鄭國興(Kuo-Hsing Cheng) 審核日期 2013-10-8
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