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研究生:曾銘松
研究生(外文):Min-Sung Tseng
論文名稱:主動矩陣式有機發光二極體驅動電路使用時間比例灰階技術之研究
論文名稱(外文):Time Ratio Grayscale Driving Circuits for Active Matrix Organic Light Emitting Diodes
指導教授:黃威黃威引用關係
指導教授(外文):Wei Hwang
學位類別:碩士
校院名稱:國立交通大學
系所名稱:電機資訊學院碩士在職專班
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:2005
畢業學年度:94
語文別:英文
論文頁數:93
中文關鍵詞:主動矩陣式有機發光二極體時間比例灰階薄膜電晶體數位驅動類比驅動
外文關鍵詞:Active Matrix Organic Light Emitting DiodesTime Ratio GrayscaleThin Film TransistorDigital DrivingAnalog Driving
相關次數:
  • 被引用被引用:2
  • 點閱點閱:1995
  • 評分評分:
  • 下載下載:0
  • 收藏至我的研究室書目清單書目收藏:1
本論文提出一個改善發光效率之設計應用於主動有機發光二極體驅動電路。而這個被驅動的畫素是以兩個電晶體及一個電容所組成的架構。藉由增加發光時間及減少定址時間來提升傳統的時間比例灰階驅動方式之發光效率。兩種可行方案被提出。取樣的移位暫存器採用倍速串列輸入將減少定址時間。振輻調變編碼的使用將減少子圖框的數目進而增加發光時間。結合上述兩種方案的驅動方式能夠提升24%的發光。較高的發光特性,將使得每個畫素面積減少,較小的畫素使得較高解析度的顯示器能夠被製造。此外將驅動電路整合在面板上是最終目標,面板上常使用的多晶矽薄膜電晶體有臨界電壓及遷移率變異的問題,而這些變異使得類比線路設計不易實現於面板上。而這個改良的時間比例灰階驅動方式也是使用數位驅動方式,在驅動電路部分它不需類比電路,他使得驅動電路完全整合於面板上將成為可能。為了正確影像顯示,另外提出掃描訊號阻絕,以防止兩個相鄰的掃描線切換時所造成的顯示資訊錯誤寫入。這個主動矩陣式有機發光二極體驅動電路是用0.6 微米18V CMOS 製程來模擬。由於點亮時間的限制,此一驅動電路適合應用於QVGA 或低於此解析度。
Using improved luminance efficiency for the driving circuit of Active Matrix Organic Light Emitting Diodes (AMOLED) is presented in this thesis. The driven pixel is based on the structure with two transistors and one capacitor. We propose to enhance the luminance efficiency of conventional time ratio grayscale by increased lighting time and decreased addressing time. Two practical approaches to enhance luminance will be proposed. For decreased addressing time, shift register of sampling adopt double rate serial-in. For increased lighting time, amplitude modulation coding will reduce the number of sub-frame, and increase the lighting time. The combined method could enhance 24%. luminance. The higher luminance allows a small pixel. Small pixel will allow high resolution displays to be created. Moreover, the final goal is that driver circuits are integrated on the display panel. TFT by poly-silicon is always adopted. For poly-silicon thin film transistor (TFT), both mobility and threshold-voltage vary randomly across the plate. The former two variables would lead to analog circuit is hard to implement on panel. The improved time ratio grayscale also adopts the digital driving. There is no analog design in driver by this method. It is possible that the driving circuit is fully implemented to System on Panel (SOP). Another proposed scan signal gating for correct image display prevent from error-programming when adjacent scan line are
toggling.
A prototype of this AMOLED driver is simulated by 0.6 um 18V CMOS technology. Because lighting time is limited, it is suitable for the Quarter Video Graphic Array (QVGA) or below the resolution.
Chapter 1: Introduction .................................................................................. 1
1.1 Keep Your Eye on The Future ............................................................. 1
1.2 History .................................................................................................. 2
1.3 Performance and Application .............................................................. 4
1.4 Scope of This Work.............................................................................. 6
Chapter 2: Related Techniques and Characterization for OLED .............. 7
2.1 LED and OLED.................................................................................... 7
2.2 PLED and OLED ................................................................................. 8
2.3 Light Emission Structure .................................................................... 9
2.4 Emission Properties .......................................................................... 10
2.5 Color Present ...................................................................................... 10
2.5.1 Patterned Lateral RGB Emitters ................................................... 11
2.5.2 Color Change Media ....................................................................... 12
2.5.3 Color Filter ...................................................................................... 12
2.5.4 Color Stacked OLED ...................................................................... 13
2.6 Electric Illumination Characterization ........................................... 14
2.7 Matrix Addressing............................................................................ 15
2.7.1 Passive Matrix ................................................................................. 16
2.7.1.1 Pixel Structure .............................................................................. 16
2.7.1.2 Pixel Addressing .......................................................................... 16
2.7.1.3 Pixel Concern ............................................................................... 17
2.7.2. Active Matrix Addressing .......................................................... 19
2.7.2.1 Pixel Structure .............................................................................. 19
2.7.2.2 Pixel Addressing .......................................................................... 20
2.7.2.3 Pixel Concern ............................................................................... 21
2.7.2.3.1 Constant Current or Source Follower....................................... 21
2.7.2.3.2 Driving Device Choice.............................................................. 22
2.7.2.3.3 IR-Drop...................................................................................... 22
2.8 Top-Emission and Bottom-Emission................................................. 23
v
Chapter 3: AMOLED Review for Driving Design ...................................... 25
3.1 Category.............................................................................................. 25
3.2 Transistor Technologies ..................................................................... 26
3.2.1 Poly Silicon ................................................................................... 26
3.2.2 Amorphous Silicon ........................................................................ 26
3.2.3 Organic Transistor ......................................................................... 27
3.2.4 Crystalline Silicon ......................................................................... 27
3.3 Analog Driving .................................................................................. 28
3.3.1 Voltage Programming Pixel............................................................ 29
3.3.1.1 Voltage Programmed with 4T2C Pixel Structure ....................... 29
3.3.1.2 Voltage Programmed with 5T1C Pixel Structure ..................... 30
3.3.2 Current Programming Pixel ......................................................... 32
3.3.2.1 Current Programmed with Current-Copy Pixel ....................... 32
3.3.2.2 Current Programmed with Current-Mirror Pixel ..................... 33
3.4 Digital Driving.................................................................................... 34
3.4.1 Area Ratio Grayscale ...................................................................... 34
3.4.2 Time Ratio Grayscale...................................................................... 35
Chapter 4: AMOLED Driver Design............................................................ 36
4.1 Active Matrix Driving........................................................................ 26
4.2 Image Display..................................................................................... 40
4.3 Data Driver ......................................................................................... 42
4.3.1 Architecture ..................................................................................... 43
4.3.2 Serial to Parallel Circuit with Double Rate Serial-in ..................... 44
4.3.2.1 Image Mirror ................................................................................ 46
4.3.3 Improved Time Ratio Grayscale with Amplitude Modulation...... 47
4.3.4 Decoder and Analog Switch ........................................................... 50
4.3.5 Simulation Result and Summary .................................................... 52
4.4 Scan Driver......................................................................................... 55
4.4.1 Architecture ..................................................................................... 55
4.4.2 Sequential Scan with Image Handstand ......................................... 56
4.4.2.1 Non-overlap with Scan Signal Gating......................................... 58
4.4.3 Cathode Electrical Switch for IR Drop Issue ................................. 60
4.4.4 Simulation Result and Summary .................................................... 62
vi
4.5 Voltage Regulator............................................................................... 63
4.5.1 Block Diagram of Voltage Regulator............................................. 65
4.5.2 Voltage Reference ......................................................................... 66
4.5.2.1 Zero Temperature Coefficient ..................................................... 67
4.5.2.2 Architecture .................................................................................. 70
4.5.2.3 Simulation Result and Summary ................................................. 72
4.5.3 Pass Device Concern....................................................................... 73
4.5.4 Frequency Response of Voltage Regulator .................................... 75
4.5.5 Voltage Regulator with OTA Structure.......................................... 77
4.5.6 Simulation Result and Summary .................................................... 79
Chapter 5: Conclusions and Future Work................................................... 81
5.1 Conclusions ........................................................................................... 81
5.2 Future Work........................................................................................... 82
References......................................................................................................... 83
In Chapter1
[1-1] Lawrence E. Tannas, “The Ultimate Avionics Display”, SID ’00 DIGEST, pp.
1145-1147, 2000.
[1-2] Sixto Ortiz Jr, “New monitor technologies are on display”, Computer, vol:36, pp. 13-16,
2003.
[1-3] Collins. L, “Roll-up displays: fact or fiction? “, IEE Review, Volume: 49, pp. 42–45,
2003.
[1-4] C. W. Tang, S.A. Van Slyke., “Organic electroluminescent diodes”, Appl. Phys. Lett.
Vol. 51, pp. 913-915, 1987.
[1-5] J.H. Burroughes, D.D.C. Bradley, A.R. Brown, R.N. Marks, K. Mackay, R.H. Friend,
P.L. Burn, A.B. Holmes, “ Light-emitting organic electroluminescent devices based on
conjugated polymers”, Nature, vol. 347, pp. 539-541,1990.
[1-6] M.T.Johnson, I.M.Hunter, N.D.Young, I.G.J.Camps, “Active matrix polyLED displays”,
IDW ’00, pp. 235-238, 2000.
[1-7] Tatsuya Shimode, Mutsumi Kimura, Satoru Miyashita, “Current status and future of
light emitting polymer display driven by poly-Si TFT”, SID ’99 DIGEST, pp. 372-375,
1999.
[1-8] G.Rajeswaran, M. Itoh, M. Boroson, “Active matrix low temperature poly-Si
TFT/OLED full color displays: development status”, SID ’00 DIGEST, pp. 974-977, 2000.
[1-9] Y. Sakaguchi, H. Tada, T. Tanaka, E. Kitazume, K. Mori, S. Kawashima, J. Suzuki,
“Color Passive-Matrix Organic LED Display using Three Emitters”, SID ’02, pp. 1182-1185,
2002.
[1-10] S. Xiong, B. Guo, C. Wu, Y. Chen, Y. Hao, Z. Zhou, H. Yang, “A Novel Design of
Sub-frame and Current Driving Method for PM-OLED”, SID ’02, pp. 1174-1176, 2002.
[1-11] A. Hunze, M. Scheffel, J. Birnstock, J. Blässing, A. Kanitz, W. Rogler, G. Wittmann,
A. Winnacker, S. Rajoelson, H. Hartmann, “Passive Matrix Displays Based on the New Red
Emitting Dopant RedATDBstors”, SID ’02, pp. 1186-1189, 2002.
[1-12] James L. Sanford, Frank R. Libsch, “TFT AMOLED Pixel Circuits and Driving
Methods”, SID ‘03 DIGEST, pp. 10-13, 2003.
[1-13] Masuyuki Ohta, Hiroshi Tsutsu, Hiroshi Takahara, Ikunori Kobayashi, Tsuyoshi
Uemura, Yoneharu Takubo, “A Novel Current Programmed Pixel for Active Matrix OLED
Displays”, SID ‘03 DIGEST, pp. 108-111, 2003.
2
In Chapter2
[2-1] Byeong-Gyu Rohr, Tae-Joon Ahn, Jae-Young Cho, Hwan-Sool Oh, “The fabrication of
green organic light-emitting-diode by evaporation process”, TENCON ’99. Proceedings of the
IEEE Region 10 Conference , vol. 2 , pp. 1103-1105,1999.
[2-2] Takahisa Shimizu, Akio Nakamura, Hatsumi Komaki, Takao Minato ,Hubert Spreitzer,
Jonas Kroeber “Fabrication Technique of PELD by Printing Methods” SID ’03 DIGEST, pp.
1290-1293, 2003.
[2-3] Tatsuya Shimoda , “Ink-jet Technology for Fabrication Processes of Flat Panel
Displays”, SID ’03 DIGEST, pp. 1178-1181, 2003.
[2-4] G.Rajeswaran, M. Itoh, M. Boroson, “Active matrix low temperature poly-Si
TFT/OLED full color displays: development status”, SID ’00 DIGEST, pp. 974-977, 2000.
[2-5] Shoustikov. A., Yujian You, Thompson, M.E. “Electroluminescence color tuning by dye
doping in organic light-emitting diodes”, IEEE Journal vol.4 , pp. 3 - 13, 1998.
[2-6] G. GU, Stephen R. Forrest, “Design of flat-panel displays based on organic
light-emitting devices”, IEEE Journal of selected topics in quantum electronics, pp. 83-99,
1998.
[2-7] C. C. Wu, J. C .Sturm, R.A. Register, M. E. Thompson, “Integrated three-color organic
light-emitting devices”, Appl. Phys. Lett., vol. 69, pp. 3117-3119, 1996.
[2-8] C. W. Tang, D. J. Williams, J. C. Chang, “Organic electroluminescent multicolor image
display device”, U.S. Patent 5294870, 1994.
[2-9] J. Kido, M. Kimura, K. Nagai, “ Multilayer white light-emitting organic
electroluminescent device”, Science, vol. 267, pp. 1332-1334, 1995.
[2-10] J. E. Littman and S. A. Vanslyke, “White light-emitting internal junction organic
electroluminescent device”, U.S. Patent 5405709, 1995.
[2-11] J. Kalinowski, P.Di Marco, M. Cocchi, V. Fattori, N. Camaioni, J. Duff,
“Voltage-tunable-color multilayer organic light emitting diode”, Appl. Phys. Lett., vol. 68, pp.
2317-2319, 1996.
[2-12] P.E. Bruuows, G. Gu, V. Bulovic, Z. Shen, S. R. Forrrest, M.E. Thompson, “Achieving
Full-Color Organic Light-Emitting Devices for Lightweight, Flat-Panel Displays”, IEEE
TRANSACTIONS ON ELECTRON DEVICES, vol. 44, NO.8, pp. 1188-1202, 1997.
[2-13] J.R. Sheats, “Stacked Organic Light-Emitting Diodes in Full Color”, Science 1997 277,
pp. 191-192, 1997.
[2-14] L E. Tannas, Jr., “ Flat Panel Displays and CRTs”, New York: Van Nostrand Reinhold,
1985.
3
[2-15] Jin Kim, J. H. Back, Giljae Lee, J. D. Noh, T. J. Kim, H. R. Ann, “A Development of
Driving Chip-set and System for 1.94” Full Color PM OLED”, SID ’03 DIGEST, pp.
1127-1129, 2003.
[2-16] M.T.Johnson, I.M.Hunter, N.D.Young, I.G.J.Camps, “Active matrix polyLED displays”,
IDW ’00, pp. 235-238, 2000.
[2-17] T. P. Brody et al, IEEE Trans Elec Dev, Vol ED-22, No 9, pp. 739-748, 1975.
[2-18] R.M.A Dawson, Z.Shen,D.A.Furst, S. Connor, J. Hsu, M.G. Kane, R.G. Stewart,
A.Ipri,C.N.King, P.J. Green, R.T. Flegal, S.Pearson, W.A. Barrow, E. Dickey, K. Ping,
C.W.Tang, S. Van Slyke, F. Chen, J. Shi, J.C. Sturm, M.H. Lu, “Design of an improved pixel
for a polysilicon active-matrix organic LED display”, SID ’98 DIGEST, pp. 11-14, 1998.
[2-19] M. J. Powell, “Bias-stress-induced creation and removal of dangling-bond states in
amorphous silicon thin-film transistors”, Appl. Phy. Lett. 60,2, pp. 207-209, 1992.
[2-20] Reiji HATTORI, Tsutomu TSUKAMIZU, Ryusuke TSUCHIYA, Kazunori MIYAKE,
Yi HE, Jerzy KANICKI, “Current-Writing Active-Matrix Circuit for Organic Light-Emitting
Diode Display Using a-Si:H Thin-Film-Transitors”, IEICE TRAN. ELECTRON.,
VOL.E83-C, NO.5, pp. 779-782, 2000.
[2-21] R.M.A.Dawson, Z. Shen, D.A. Futst, S. Connor, J. Hsu, M.G. Kane, R.G. Stewart, A.
Ipri, C.N. King, P.J. Green, R.T. Flegal, S. Pearson, W.A. Barrow, E. Dickey, K. Ping, S.
Robinson, C.W. Tang, S. Van Slyke, C.H. Chen, J. Shi, M.G. Lu, M. Moskewicz, J.C. Sturm,
“A polysilicon active matrix organic light emitting diode display with integrated drivers”,
SID ’99 DIGEST, pp. 438-441, 1999.
[2-22] R.M.A.Dawson, Z. Shen, D. A. Furst, S. Connor, J. Hsu, M. G. Kane, R. G. Stewart, A.
Ipri, C. N. King, P. J. Green, R. T. Flegal, S. Pearson, W. A. Barrow, E. Dickey, K. Ping, S.
Robinson, C. W. Tang, S. Van slyke, F. Chen, J. Shi, M. H. Lu, J. C. Sturm,“The impact of the
transient response of organic light emitting diodes on the design of active matrix OLED
displays”, IEDM ’98, pp. 875-878, 1998.
[2-23] Simon W.-B. Tam, Yojiro Matsueda, Mutsumi Kimura, “Improved polysilicon TFT drivers
for light emitting polymer display”, IDW ’00, 00 243-246, 2000
[2-24] T.Sasaoka, M Shimoda, Piero Migliorato, “ Poly-Si Driving Circuits for Organic EL
Displays”, Electronic.Sekiya, A.Yumoto, J.Yamada, T.Hirano, Y.Iwase, T.Yamada, T.Ishibashi,
T.Mori, M.Asano, S.Tamura, T.Urabe, “ A 13.0 inch AMOLED Display witho TOP Emitting
Structure and Adaptive Current Mode Programmed Pixel Circuit,TAC”, SID ‘01, pp. 384-387,
2001.
4
In Chapter3
[3-1] D. Pribhat, F. Palis, “Matrix addressing for organic electroluminescent displays”, Thin
Solid Films, 383, pp. 25-30, 2001.
[3-2] Simon W.-B. Tam, Yojiro Matsueda, Mutsumi Kimura, Hiroshi Maeda, Tatsuya Shimoda ,
Piero Migliorato “ Poly-Si Driving Circuits for Organic EL Displays”, Electronic Imageing 2001,
pp. 4920-4925, 2001.
[3-3] Reiji Hattori, Tsutomu Tsukamizu, “Current-writing active-matrix circuit for organic
light-emitting diode display using a-Si:H thin-film-transistors”, IEICE TRANS.Electron,
VOL-E83-C,NO.5, pp. 779-782, 2000.
[3-4] G. GU, Stephen R.Forrest, “Design of flat-panel displays based on organic light-emitting
devices”, IEEE Journal of selected topics in quantum electronics, pp. 83-99, 1998.
[3-5] J.J.Lih, C.F.Sung, M.S.Weaver, M.Hack,J.J.Brown, “A phosphorescent Active-Matrix
OLED Display driven by Amorphous Silicon Backplane”, SID ’03 DIGEST, pp. 14-17, 2003.
[3-6] R.M.A.Dawson, M.G.Kane, “Pursuit of active matrix organic light emitting diode
displays”, SID ’01 DIGEST, pp. 372-375, 2001.
[3-7] M.T.Johnson, I.M.Hunter,N.D.Young, I.G.J.Camps, “Active matrix polyLED displays”,
IDW ‘00, pp.235-238, 2000.
[3-8] Yi He, Reiji Hattori, Jerzy Kanicki, “Current-source a-Si:H thin-film-transistor circuit
for active-matrix organic light-emitting displays”, IEEE ELECTRON DEVICE LETTER ’00,
pp. 590-592, 2000.
[3-9] Takashi Chuman, Satoru Ohta, Satoshi Miyaguchi, Hideo Satoh, Takahisa Tanabe,
Yoshiyuki Okuda, Masami Tsuchida, “Active Matrix Organic Light Emitting Diode Panel using
Organic Thin-Film Transistors”, SID ’04 DIGEST, pp. 45-47, 2004.
[3-10] R.M.A.Dawson, Z. Shen, D.A. Futst, S. Connor, J. Hsu, M.G. Kane, R.G. Stewart, A.
Ipri, C.N. King, P.J. Green, R.T. Flegal, S. Pearson, W.A. Barrow, E. Dickey, K. Ping, S.
Robinson, C.W. Tang, S. Van Slyke, C.H. Chen, J. Shi, M.G. Lu, M. Moskewicz , J.C. Sturm,
“A polysilicon active matrix organic light emitting diode display with integrated drivers”,
SID ’99 DIGEST, pp. 438-441, 1999.
[3-11] R.M.A Dawson, Z.Shen,D.A.Furst, S. Connor, J. Hsu, M.G. Kane, R.G. Stewart,
A.Ipri,C.N.King, P.J. Green, R.T. Flegal, S.Pearson, W.A. Barrow, E. Dickey, K. Ping,
C.W.Tang, S. Van Slyke, F. Chen, J. Shi, J.C. Sturm, M.H. Lu, “Design of an improved pixel
for a polysilicon active-matrix organic LED display”, SID ’98 DIGEST, pp. 11-14, 1998.
5
[3-12] Sang-Moo Choi, Oh-Kyong Kwon, Ho-Kyun Chung, “An improved voltage
programmed pixel structure for large size and high resolution AM-OLED displays”, SID ’04
DIGEST, pp. 260-263, 2004.
[3-13] Yang-Wan Kim, Oh-Kyong Kwon, Keum-nam Kim, Dong- Young Shin, Byung-Hee
Kim, Ho-Kyoon Chung, “A New Current Programmable Pixel Structure for Large-Size and
High-Resolution AMOLEDs”, IDW, international Symp. Proc., pp. 367-369, 2002.
[3-14] Masuyuki Ohta, Hiroshi Tsutsu, Hiroshi Takahara, Ikunori Kobayashi, Tsuyoshi Uemura,
Yoneharu Takubo, “A novel current programmed pixel for active matrix OLEDs”, SID ’03
DIGEST, pp. 108-111, 2003.
[3-15] James L. Sanford, Frank R. Libsch, “TFT AMOLED Pixel Circuits and Driving
Methods”, SID ’03 DIGEST, pp. 10-13, 2003.
[3-16] T. Sasaoka, M. Sekiya, A. Yamagata, J. Yamada, T. Hirano, Y.Iwase, T. Yamada, T.
Mori, M. Asano, S. Tamura, T. Urabe, “A 13.0-inch AM-OLED display with top emitting
structure and adaptive current mode programmed pixel circuit”, SID ’01 DIGEST, pp. 384-387,
2001.
[3-17] K Inukai, H Kimura, M Mizukami, J. Maruyma, S.Murakami, J. Koyama, T, Konuma , S.
Yamazaki, “4.0-in. TFT-OLED displays and a novel digital driving method”, SID ’00, pp.
924-927, 2000.
[3-18] M Mizukami, K Inukai, H Yamagata, T. Konuma, T.Nishi, J. Koyama, S. Yamazaki , ‘T.
Tsutsui , “6-Bit digital VGA OLED”, SID ’00, pp. 912-915, 2000.
In Chapter4
[4-1] James L. Sanford, Frank R. Libsch "TFT AMOLED Pixel Circuits and Driving
Methods", SID ’03 DIGEST, pp.10-13, 2003.
[4-2] R.M.A. Dawson et al., U.S. Pat. 6307322, 2001.
[4-3] Childs M, Nisato G, Fish D, Giraldo A, Jenkins A, Johnson M, “Advance Poly-LED
Displays”, Philips Research Laboratories Redhill, to be published., 2003.
[4-4] K Inukai, H Kimura, M Mizukami, J. Maruyma, S.Murakami, J. Koyama, T, Konuma , S.
Yamazaki, “4.0-in. TFT-OLED displays and a novel digital driving method”, SID ’00, pp.
924-927, 2000.
[4-5] Ju Young Jeong, Jaegeun Kim, “ Dual Modulation Driving for Poly-Si TFT Active Matrix
OLED Displays”, IDW ’03, pp. 551-554, 2003.
[4-6] M Mizukami, K Inukai, H Yamagata, T. Konuma, T.Nishi, J. Koyama, S. Yamazaki , ‘T.
Tsutsui , “6-Bit digital VGA OLED”, SID ’00, pp. 912-915, 2000.
[4-7] Yen-Shyung Shyu, “Low Operating Current Analog Integrated Circuits”, NCTU, Phd.
Thesis, Jun. 2002.
6
[4-8] Zi-Long Hung, “A Precision 2.5V to 1.8V Low Dropout Voltage Drgulator”, NCKU,
Master Thesis, Jun. 2003.
[4-9] Band S. Lee, “Understanding the Terms and Definitions of LDO Voltage Regulator”,
Texas Instruments Inc., Application Report, to be published.
[4-10] Band S. Lee, “Technical Review of Low Dropout Voltage Regulator Operation and
Performance” , Texas Instruments Inc., Application Report, to be published.
[4-11] Gabriel A. Rincon-Mora, “Active Capacitor Multiplier in Miller-Compensated Circuits”,
IEEE TRANSACTIONS ON SOLID-STATE CIRCUITS, vol. 35, No.1, pp. 26-32, 2000.
[4-12] Ka Namg Leung, K.T. Mok, Wing Hung Ki, “A Novel Frequency Compensation
Technique for Low-Voltage Low Dropout Regulator”, IEEE ISCAS 1999, pp.102-105, 1999.
[4-13] Ka Chun Kwok, K.T. Mok, “Pole-Zero Tracking Frequency Compensation for Low
Dropout Regulator”, ISCAS 2002, pp.735-738, 2002.
[4-14] R. Jacob Baker, “CMOS Circuit Design, Layout and Simulation”, John Wiley & Sons
Inc., 2005.
[4-15] PAUL R. GRAY et al., “Analysis and Design of Analog Integrated Circuits”, John Wiley
& Sons Inc., 2001.
[4-16] Behzad Razavi, “Design of Analog CMOS Integrated Circuits”, McGRAW-HILL Inc.,
2001.
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