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姓名 陳琮智(Tsung-Chih Chen) 查詢紙本館藏 畢業系所 電機工程學系 論文名稱 電感結合充電電荷泵浦之新型可調節式升壓型直流-直流轉換器設計
(A Novel Design of Adjustable Step-Up Charge Pump DC to DC Converter with Inductor)相關論文 檔案 [Endnote RIS 格式] [Bibtex 格式] [相關文章] [文章引用] [完整記錄] [館藏目錄] [檢視] [下載]
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摘要(中) 本文鑑於傳統之充電電荷泵浦(Charge Pump)其調壓控制困難且複雜,提出將電感結合充電電荷泵浦之可調節式升壓型直流-直流轉換器設計,基於充電電荷泵浦之基礎加入電感器設計,結合切換式轉換器(Switching Converter)架構之優點,使其大幅提高線性調節度與轉換效率,在架構上簡化控制器設計之複雜度,並透過詳盡計算分析,使架構之各項參數與規格可透過公式計算得知,以增加本架構於應用時之便利性。最後以模擬和實際製作電路,驗證本電路確實可行且具其效果。
本文提出之電路架構改善直流轉換器之兩項重要參數-效能(最大可達 97.5%)與負載調節度(0.76mV/mA),此外電壓轉換比例可由責任週期調整,不再受限於電路架構,使控制更直覺以及大幅降低設計之複雜度。摘要(英) The charge pump circuits are usually not regulated in the past, or detect the current of the capacitance be a feedback signal. That is difficult to make controller and can’t get higher efficiency and need more current detector. To enhance the accuracy and the stability, this thesis presented a novel design of step up regulated charge pump which coupled inductor and design the feedback circuit by an un-complex voltage feedback to control the charging duty retio. The power efficiency also can be improvement by the new topology. As a result, the battery life can be increased, which makes charge pump more attractive.
The measured results show that the input voltage indeed can be step up to the desired output voltage. The new structure improves the efficiency(97.5%)、load regulation(0.76mV/mA) of the charge pump circuit. Furthermore, the regulated scheme makes the voltage conversion ratio no longer predetermined by the converter topology, and can be varied by adjusting the duty ratio.關鍵字(中) ★ 充電電荷泵浦
★ 倍壓
★ 直流-直流轉換器
★ 切換式電容關鍵字(英) ★ Charge Pump
★ Step-up
★ DC-DC Converter
★ Switched-capacitor論文目次 摘 要................................................. i
Abstract.............................................. ii
誌 謝................................................. iii
目 錄................................................. iv
圖目錄................................................. vi
表目錄................................................. ix
第一章 緒論 ............................................ 1
1-1研究動機 ............................................ 1
1-2研究目的 ............................................ 2
1-3論文架構 ............................................ 2
第二章 充電電荷泵浦發展技術背景............................ 3
第三章 電路設計......................................... 12
3-1主要電路 ............................................ 12
3-3-1 切換操作說明 ..................................... 14
3-3-2 輸出電壓增益計算 ................................. 18
3-3-3 轉換效能計算 ..................................... 19
3-3-4 電感值設計與輸出漣波電流計算 ........................ 20
3-3-5 連續(CCM)與不連續(DCM)導通之邊界 ................ 22
3-3-6 電容設計與輸出連波電壓計算 ......................... 24
3-4小訊號分析 .......................................... 26
3-5模擬結果 ............................................ 30
3-5-1 漣波電流漣波電壓模擬結果 ........................... 30
3-5-2 小訊號模型模擬結果 ................................ 31
第四章 硬體電路實現與實驗量測結果........................... 33
4-1硬體架構 ............................................ 33
4-2量測結果 ............................................ 37
第五章 結論.............................................. 44
5-1結論 ................................................ 44
5-2未來展望 ............................................ 44
參考文獻................................................ 45參考文獻 [1] A.K.P Viraj and G.A.J Amaratunga, “A Monolithic CMOS 5V/1V Switched Capacitor DC-DC Step-down Converter,” IEEE PESC, pp. 2510-2514, June 2007.
[2] Y.W. Lu, G. Feng, Y.F. Liu, “A Large Signal Dynamic Model for DC-to-DC Converters with Average Current Control,” IEEE APEC ‘04, vol. 2, pp. 797-803.
[3] L. Pylarinos, “Charge pumps: an overview,” University of Toronto, Tutorial Papers on Analog Circuits, 2002.
[4] J.F. Dickson, “On-chip High-Voltage Generation in NMOS Integrated Circuits Using an Improved Voltage Multiplier Technique,” IEEE Journal of Solid-State Circuits, Vol. 11, No. 6, pp. 374-378, 1976.
[5] J.T. Wu and K.L. Chang, “MOS charge pumps for low-voltage operation,” IEEE Journal of Solid-State Circuits, Vol. 33, pp. 592-597, 1998.
[6] M.S. Makowski, “Realizability conditions and bounds on synthesis of switched-capacitor DC-DC voltage multiplier circuits,” IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, Vol. 44, pp. 684-691, 1997.
[7] J.A. Starzyk, Y. W. Jan and F. Qui,“A DC-DC charge pump design based on voltage doublers,” IEEE Transactions on Circuits and Systems I: Fundamental Theory and Applications, Vol. 48, pp. 350-359, 2001.
[8] B.Kormann and J. Pelfrey, “Simple design of an ultra-low-ripple dc/dc boost converter with TPS60100 charge pump,” Journal of Analog Applications, Texas Instruments Literature, No. SLYT015, pp. 15-18, 2000.
[9] B.Kormann and J. Pelfrey, “High-efficiency, regulated charge pumps for high-current applications,” Texas Instruments Power Supply Design Seminars, 2001.
46
[10] C.C. Wang and J.C. Wu, “Efficiency improvement in charge pump circuits,” IEEE Journal of Solid-State Circuits, Vol. 32, pp. 852-860, 1997.
[11] W.H. Ki, F. Su and C.Y. Tsui, “Charge redistribution loss consideration in optimal charge pump design,” in proceedings of the IEEE International Symposium of Circuits and Systems, Vol. 2, pp. 1895-1898, 2005.
[12] A. Saiz-Vela, P. Miribel-Catala, J. Colomer, M. Puig-Vidal and J. Samitier, “Accurate design of Two-Phase Voltage Doublers based on a compact mathematical model,” in proceedings of the IEEE International Symposium of Circuits and Systems, pp. 213-216, 2007.
[13] L. Shir-Kuan, "Design and Implementation of Boost Charge Pump Circuit of Energy Harvesting System,"NCTU MS., Thesis, 2009.
[14] B.Robert Gregoire, “A Compact Switched-Capacitor Regulated Charge Pump Power Supply,” IEEE J. Solid-State Circuits, vol. 41, no. 8, pp. 1944-1953, Aug. 2006.
[15] J.-J. Huang,“Implementation of Series Equalization by Switching Capacitor for Hybrid Battery System"NCU MS., Thesis, 2011.指導教授 徐國鎧(Kuo-Kai Shyu) 審核日期 2013-8-2 推文 facebook plurk twitter funp google live udn HD myshare reddit netvibes friend youpush delicious baidu 網路書籤 Google bookmarks del.icio.us hemidemi myshare