Buck轉換器回授補償控制器設計

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：28

、訪客IP：3.137.183.57

姓名

陳偉毅(Wei-I Chen) 查詢紙本館藏

畢業系所

電機工程學系在職專班

論文名稱

Buck轉換器回授補償控制器設計
(Feedback Compensation Design for Buck Converter)

相關論文

★ 感光式觸控面板設計	★ 單級式直流無刷馬達系統之研製
★ 單級高功因LLC諧振電源轉換器之研製	★ 多頻相位編碼於穩態視覺誘發電位之大腦人機介面系統設計
★ 類神經網路於切換式磁阻馬達轉矩漣波控制之應用	★ 感應馬達無速度感測之直接轉矩向量控制
★ 具自我調適導通角度功能之切換式磁阻馬達驅動系統---DSP實現	★ 感應馬達之低轉速直接轉矩控制策略
★ 加強型數位濾波器設計於主動式噪音控制之應用	★ 非匹配不確定可變結構系統之分析與設計
★ 無刷直流馬達直接轉矩控制方法之轉矩漣波改善	★ 無轉軸偵測元件之無刷直流馬達驅動器研製
★ 無轉軸偵測元件之開關磁阻馬達驅動系統研製	★ 感應馬達之新型直接轉矩控制研究
★ 同步磁阻馬達之性能分析及運動控制研究	★ 改良比例積分與模糊控制器於線性壓電陶瓷馬達位置控制

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]

本電子論文使用權限為同意立即開放。
已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。
請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。

摘要(中)

在直流電源轉換器的應用上，最重要的要求是提供一個穩定的直流電源，同時能對於負載的瞬間變化提供快速的反應去補償輸出電壓，以達到穩定輸出的目的，所以回授補償迴路的設計成為一個非常重要的部分。在傳統的線性(Linear)穩壓方式，因為是使用主動元件直接降壓的方式提供輸出，同時直接消耗降壓於元件上，這種型式的速度較快且沒有相位的問題，但是輸出電流低、效率低且會產生熱造成產品過熱。Buck轉換器是目前最廣泛被使用的直流電源轉換器之一，本身含有電感與電容等元件，且工作在特定的頻寬內，能提供較高輸出電流，效率較高且產生較低的熱。但是因為有電感與電容的共振頻率的響應及切換頻率的影響等因素，所以相較於線性的穩壓器，Buck轉換器需要一個可以補償其響應的回授補償迴路去穩定輸出。目前的回授補償迴路是以操作放大器為基礎所組成的回授補償線路，能提供不同頻率的補償及增益的調整，以達到補償的目的。
本論文將以Buck轉換器為基礎，去探討回授補償迴路的線路設計，並分析各種線路的優缺點及適用性。分析的過程會由理論基礎開始，包含模型的建立、轉移函數的推導等，然後是線路的設計及模擬分析。設計過程會運用Matlab及PSIM軟體去模擬及驗證設計後的實際響應。最後將會提出一個新的回授補償線路設計以針對多電源系統及遠端回授控制的穩定度需求，去對上述回授補償線路進行改善設計。因為當一個多電源系統中的各個電源共用相同的基準電位時，亦即共用相同的接地時，各個電源轉換器將被互相影響以致於無法用上述的回授補償迴路去穩定輸出電壓，同時遠端回授控制的穩定度也會因接地阻抗的影響而失真。這個新線路設計的導入將可以結合上述的回授補償線路以提高系統的穩定度。

摘要(英)

In the application of DC power converter system, the most important requirement is to provide a stable output and to have fast transient response to the loads. The design of feedback compensation loop becomes an important part in power converter system design. Current feedback compensation design is based on operational amplify to form a feeback circuit loop network that can compensate amplitude and phase of system. Buck converter is one of the well-used types in application currently. In this thesis, Buck convert will be used to explor the circuit realization of feedback compensation loop and analyze the application of most kinds of compensation circuits. The work will be start from theory analysis, which includes model establishment and transfer function generation, and then followed by circuit design and realization. All the workable circuits will be verified by MATLAB and PSIM simulation tool. The result will provide the guideline for designing feedback compensation loop. In the last part of the thesis, a specifically new designed circuit will be introduced to improve and optimize the original compensation circuits for the requirement of a system with multi-power supplies, and to optimize remote control function. It will be combined into original designed compensation circuits to provide an optimized feedback control to enhance the stability of system.

關鍵字(中)

★ 直流電源轉換器
★ Buck轉換器
★ 回授補償迴路

關鍵字(英)

論文目次

摘要i
Abstractii
誌謝iii
目錄iv
圖目錄vii
第一章緒論1
1-1 研究動機與目的1
1-2 論文架構3
第二章 Buck轉換器的模型及設計4
2-1 Buck轉換器的ac小訊號模型4
2-2 Buck轉換器之轉移函數推導13
2-2-1 不含等效串聯電阻ESR的Buck轉移函數14
2-2-2 含等效串聯電阻ESR的Buck轉移函數17
2-3 Buck轉換器的設計分析19
2-4 回授補償迴路的介紹與設計25
第三章回授補償線路之設計31
3-1 補償線路的轉移函數介紹31
3-2 振幅及相位的關係32
3-3 振幅的近似分析33
3-4 相位的近似分析34
3-5 補償後的系統總相位分析38
3-6 補償線路的分類及設計分析39
3-6-1 Buck轉換器的補償線路設計目標40
3-6-2 比例 (Proportional) 對Buck轉換器的補償分析40
3-6-3 單一反向零點對Buck轉換器的補償分析40
3-6-4 單一反向極點對Buck轉換器的補償分析47
3-6-5 單一DC極點對Buck轉換器的補償分析50
3-6-6 單一極點對Buck轉換器的補償分析54
3-6-7 單一DC零點對Buck轉換器的補償分析56
3-6-8 單一零點對Buck轉換器的補償分析56
3-6-9 1個零點+1個反相零點對Buck轉換器的補償分析57
3-6-10 1個極點+1個反相極點對Buck轉換器的補償分析58
3-6-11 1個零點+1個極點對Buck轉換器的補償分析59
3-6-12 一個零點+1個DC極點+1個極點對Buck轉換器的補償分析65
3-6-13 1個零點+2個極點對Buck轉換器的補償分析68
3-6-14 1個零點+1個DC零點+1個極點對Buck轉換器的補償分析71
3-6-15 2個零點+1個極點對Buck轉換器的補償分析71
3-6-16 1個零點+1個DC零點+2個極點對Buck轉換器的補償分析71
3-6-17 2個零點+1個DC極點+1個極點以及2個零點+2個極點對Buck轉換器的補償分析72
3-6-18 2個零點+1個DC零點+2個極點對Buck轉換器的補償分析76
3-6-19 2個零點+1個DC極點+2個極點對Buck轉換器的補償分析76
第四章回授補償之改善設計84
4-1 電源迴路之共同接地路徑問題描述84
4-2 電源迴路之共同接地路徑問題分析87
4-3 基於回授補償迴路的穩壓改善線路設計89
4-4 穩壓改善線路模擬分析92
4-5 包含小訊號之穩壓改善線路93
4-6 含小訊號的穩壓改善線路之模擬驗證96
第五章結論與未來展望101
5-1 結論101
5-2 未來展望102
附錄一：含有ESR的Buck轉換器轉移函數推導103
附錄二：補償線路列表104
參考文獻113

參考文獻

[1]Mor Mordechai Peretz and Shmuel (Sam) Ben-Yaakov, “Time-Domain Design of Digital Compensators for PWM DC-DC Converters”, IEEE Transactions on Power Electronics, Vol. 27, No. 1, pp. 284 - 293, Jan 2012
[2]Mingzhi He and Jianping Xu, “Digital Predictive V2 Control of Switching DC-DC Converters”, IEEE International Conference on Industrial Technology (ICIT), pp. 116-120, Dec 2006.
[3]Kuang-Yao (Brian) Cheng, Feng Yu, Fred C. Lee and Paolo Mattavelli, “Digital Enhanced V2-Type Constant On-Time Control Using Inductor Current Ramp Estimation for a Buck Converter With Low-ESR Capacitors”, IEEE Transactions on Power Electronics, Vol. 28, No. 3, pp. 1241 - 1252, Mar 2013.
[4]Jian Li and Fred C. Lee, “Digital Current Mode Control Architecture With Improved Performance for DC-DC Converters”, Twenty-Third Annual IEEE, Applied Power Electronics Conference and Exposition (APEC) 2008, pp. 1087 - 1092, Feb 2008.
[5]Shangyang Xiao, Weihong Qiu, Greg Miller, Thomas X. Wu and Issa Batarseh, “Adaptive Modulation Control for Multiple-Phase Voltage Regulators”, IEEE Transactions on Power Electronics, Vol. 23, No. 1, Jan 2008.
[6]Ali Emadi, “Modeling and Analysis of Multiconverter DC Power Electronic Systems Using the Generalized State-Space Averaging Method”, IEEE Transactions on Industrial Electronics, Vol. 51, No. 3, Jun 2004.
[7]George Schuellein, “Current Sharing of Redundant Synchronous Buck Regulators Powering High Performance Microprocessors using the v2 Control Method”, Applied Power Electronics Conference and Exposition (APEC) 1998, Vol. 2, pp. 853 - 859, 1998.
[8]Robert W. Erickson, Dragan Maksimovic, “Fundamentals of Power Electronics” 2nd edition, Kluwer Academic Publishers. 2001.
[9]R.D.Middlebrook and Slobodan `Cuk, “A General Unified Approach to Modeling Switching-Converter Power Stages,” International Journal of Electronics, Vol. 42, No. 6, pp. 521-550, Jun 1977.
[10]Slobodan `Cuk, “ Modeling, Analysis, and Design of Switching Converters”, Ph.D. thesis, California Institute of Technology, Nov 1976.
[11]Tsai-Fu Wu and Yu-Kai Chen, “A Systematic and Unified Approach to Modeling PWM DC/DC Converters Based on the Graft Scheme”, IEEE Transactions of Industrial Electronics, Vol. 45, No. 1, Feb 1998.
[12]Vatcherian, Richard Tymerski and Fred C. Y. Lee, “Equivalent Circuit Models for Resonant and PWM Switches”, IEEE Transactions on Power Electronics, Vol. 4, No. 2, Apr 1989.
[13]Philip T. Krein, Joseph Bentsman, Richard M. Bass and Bernard L.Lesieutre, “On the use of averaging for the analysis of power electronic systems”, IEEE Transactions on Power Electronics. Vol. 5, No. 2, Apr 1990.
[14]Seth R. Sanders and George C. Verghese, “Synthesis of Averaged Circuit Models for Switched Power Converters”, IEEE Transactions on Circuits and Systems, Vol. 38, No. 8, Aug 1991.
[15]Vatche Vorperian, Simplified Analysis of PWM Converters Using the Model of the PWM Switch: Part I”, IEEE Transactions on Aerospace and Electronic Systems, Vol. AES-26, No. 3, May 1990.
[16]Brigitte Hauke, “Basic Calculation of a Buck Converter’s Power Stage”, TI Application Report, SLVA477A-December 2011, Revised August 2012
[17]Chongming Qiao, Jason Zhang, Parviz Parto and David Jauregui, “Output Capacitor Comparison for Low Voltage High Current Applications”, 351h Annual IEEE Power Electronics Specialists Conference, Vol. 1, pp. 622 - 628, 2004.
[18]Shangyang Xiao, Weihong Qiu, Greg Miller, Thomas X. Wu and Issa Batarseh, “An Active Compensator Scheme for Dynamic Voltage Scaling of Voltage Regulators”, IEEE Transactions on Power Electronics, Vol. 24, No. 1, Jan 2009.
[19]Kaiwei Yao, Ming Xu, Yu Meng and Fred C. Lee, “Design Considerations for VRM Transient Response Based on the Output Impedance”, IEEE Transactions on Power Electronics, Vol. 18, No. 6, Nov 2003.
[20]Amir M. Rahimi, Parviz Parto and Peyman Asadi, "Compensator Design Procedure for Buck Converter with Voltage-Mode Error-Amplifier”, IR, International Rectifier, AN-1162.
[21]Michael (Chongming) Qiao, Parviz Parto and Reza Amirani, “Stabilize the Buck Converter with Transconductance Amplifier”, IR, International Rectifier, AN-1043.
[22]Jim Sun, “Control Design Considerations for Voltage Regulator Modules”, 25th International Telecommunications Energy Conference (INTELEC), pp. 84 - 91, Oct 2003
[23]David, C. W. Ng, William Y.T. Wong, Ngai Wong, Karen W. H. Wan and David K. K. Kwong, “An Efficient Transfer-Function-Based Approach for the fast tuning and Design of DC-DC Converter”, Second IEEE Conference on Industrial Electronics and Applications (ICIEA), pp. 682 - 686, May 2007.
[24]Patrick Y. Wu, Sam Y. S. Tsui and Philip K. T. Mok, “Area- and Power-Efficient Monolithic Buck Converters With Pseudo-Type III Compensation”, IEEE Journal of Solid-State Circuits, Vol. 45, No. 8, Aug 2010.
[25]Keyue M. Smedley and Slobodan `Cuk, “One-Cycle Control of Switching Converters”, IEEE Transactions on Power Electronics, Vol. 10, No. 6, Nov 1995.
[26]Ke-Horng Chen, Hong-Wei Huang and Sy-Yen Kuo, “Fast-Transient DC–DC Converter With On-Chip Compensated Error Amplifier”, IEEE Transactions on Circuit and Systems-II: Express Briefs, Vol. 54, No. 12, Dec 2007.
[27]Vratislav Michal, Christophe Premont, Gael Pillonet and Nacer Abouchi, “Active Element PID Controllers”, 20th International Conference, pp. 1-4, Apr 2010.
[28]Vratislav Michal, Christophe Premont, Gael Pillonet and Nacer Abouchi, “Zero-derivative Method of Analog Controller Design Applied to Step-down DC-DC Converters”, IEEE International Symposium on Circuits and Systems (ISCAS), Proceedings of 2010, pp. 2920 - 2923, May 30 2010-June 2 2010.
[29]Zdravko Lukic, Aleksandar Prodic, and Zhenyu Zhao, “Self-Tuning Sensorless Digital Current-Mode Controller with Accurate Current Sharing for Multi-Phase DC-DC Converters”, Twenty-Fourth Annual IEEE Applied Power Electronics Conference and Exposition (APEC), pp. 264 - 268, Feb 2009.
[30]Guo Guoyong and Shi Bingxue, “Design of Multi-phase DC-DC Converter with Master-Slave Current Sharing Control”, IEEE Region 10 Conference on Computers, Communications, Control and Power Engineering (TENCON) Proceedings. 2002, Vol. 3, pp. 1990 - 1993, Oct 2002.
[31]Yu-Huei Lee, Kuan-Yu Chu, Chun-Jen Shih and Ke-Horng Chen, “Proportional Compensated Buck Converter With a Differential-In Differential-Out (DIDO) Error Amplifier and Load Regulation Enhancement (LRE) Mechani”, IEEE Transactions on Power Electronics, Vol. 27, No. 5, May 2012.
[32]Song Qu, “Modeling and Design Considerations of V2 Controlled Buck Regulator”, Sixteenth Annual IEEE Applied Power Electronics Conference and Exposition (APEC), Vol. 1, pp. 507 - 513, 04 Mar 2001-08 Mar 2001.

指導教授

徐國鎧

審核日期

2013-8-2

推文