功率放大器非線性度分析
與毫米波次諧波混頻器電路設計

Shih-Yu Chen; 陳詩喻

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/32526

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	黃天偉
dc.contributor.author	Shih-Yu Chen	en
dc.contributor.author	陳詩喻	zh_TW
dc.date.accessioned	2021-06-13T04:11:18Z	-
dc.date.available	2006-07-27
dc.date.copyright	2006-07-27
dc.date.issued	2006
dc.date.submitted	2006-07-25
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Wang, “A 38-48-GHz Miniature MMIC Subharmonic Mixer,” in European Microwave Conference Proceedings, Oct. 2005. [7] K. S. Ang, A. H. Baree, S. Nam, and I. D. Robertson, “A millimeter-wave monolithic sub-harmonically pumped resistive mixer,” in Proc. Asia-Pacific Microwave Conf., vol. 2, pp. 222-225, 1999. [8] M. F. Lei, P. S. Wu, T. W. Huang, H. Wang, ” Design and analysis of a miniature W-band MMIC subharmonically pumped resistive mixer,” 2004 IEEE MTT-S Int. Microwave Sym., vol. 1, pp. 235-238, June 2004. [9] W. Xinwei, H. Nakamura, and R. Singh, “ACPR, IM3 and their correlation for PCS CDMA power amplifier,” in 50th ARFTG Dig., Dec. 1997, pp.91-96. [10] P. Yin, “A Simplified Approximation Method for Cascaded System Adjacent and Alternative Channel Power Ratio,” Applied Microwave & Wireless Magazine, pp. 70-76, 2003. [11] M. Leffel, “Inter-modulation distortion in a multi-signal environment,” RF Design, pp.78-84, Jun. 1995. [12] Pedro, J. C., and N. B. De Carvalho, “On the use of multitone techniques for assessing RF components’ intermodulation distortion,” IEEE Trans. on Microwave Theory and Techniques, vol. 47, No. 12, pp. 2393-2402, Dec. 1999. [13] Carvalho, N. B. and J. C. Pedro, “Multi-tone intermodulation distortion performance of 3rd order microwave circuits,” IEEE Symposium on Microwave Theory and Techniques, Anaheim, USA, vol. 2, pp. 763-766, Jun. 1999. [14] Carvalho, N. B. and J. C. Pedro, “Compact formulas to relate ACPR and NPR to two-tone IMR and IP3,” Microwave J., pp. 70-84, Dec. 1999. [15] N. Boulejfen, A. Harguem, and F. M. Ghannouchi, “New closed-form expressions for the prediction of multitone intermodulation distortion in fifth-order nonlinear RF circuits/systems,” IEEE Trans. on Microwave Theory and Techniques, vol. 52, No. 1, pp. 121-132, Jan. 2004. [16] N. Boulejfen, A. Harguem, and F. M. Ghannouchi, “Intermodulation distortion in fifth-order nonlinear RF circuits/subsystems under multitone excitation,” 33rd European Microwave Conference, pp. 763-766, 2003. [17] Q. Wu, M. Testa, and R. Larkin, “Linear RF power amplifier design for CDMA signals,” in IEEE MTT-S Int. Microwave Symp. Dig., 1996, pp.851-854. [18] Q. Wu, M. Testa, and R. Larkin, “On design of linear RF power amplifier for CDMA signals,” Int. J. Microwave Millimeter-Wave Computer-Aided Eng., pp.283-292, Feb.1998. [19] Q. Wu, H. Xiao, and F. Li, “Linear RF power amplifier design for CDMA signals: A spectrum analysis approach.” Microwave J., pp.22-40, Dec.1998. [20] J. S. Ko; J. K. Kim; B. K. Ko; D. B. Cheon; B. H. Park, “Enhanced ACPR technique by class AB in PCS driver amplifier,” VLSI and CAD, 1999. ICVC '99. 6th International Conference on, 26-27, pp. 376 – 379, Oct. 1999. [21] S. J. Yi, S. Nam, S. H. Oh, and J. H. Han, “Prediction of a CDMA output spectrum based on intermodulation products of two-tone test.” IEEE Trans. on Microwave Theory and Techniques, vol. 49, No. 5, pp. 938-946, May. 2001. [22] V. Aparin, B. Butler, and P. Draxler, “Cross modulation distortion in CDMA receivers,” in IEEE MTT-S int. Microwave Symp. Dig., vol. 3, pp. 1953-1956, 2000. [23] V. Aparin, “Analysis of CDMA Signal Spectral Regrowth and Waveform Quality,” IEEE Trans. on Microwave Theory and Techniques, vol. 49, no. 12, pp. 2306-2314, Dec. 2001. [24] V. Aparin, “Analysis and Reduction of Cross-Modulation Distortion in CDMA Receivers,” IEEE Trans. on Microwave Theory and Techniques, vol. 51, no. 5, pp. 1591-1602, May 2003. [25] V. Aparin, and L. E. Larson, “Analysis of Cross Modulation in W-CDMA Receivers,” in IEEE MTT-S int. Microwave Symp. Dig., vol. 2, pp. 787-790, June 2004. [26] J. C. Pedro, and N. B. Carvalho, “Statistics of Microwave Signals and Their Impact on the Response of Nonlinear Dynamic Systems,” 62nd ARFTG Microwave Measurements Conference, pp. 143-153. [27] B. Razavi, RF Microelectronics, Prentice Hall Publishers, 1998. [28] 張鴻埜 “毫米波反射式調變器之研究及其應用 Research on millimeter-wave reflection-type modulators and their applications” 國立台灣大學電信工程研究所博士論文, 民國93年, 2004. [29] P. B. Kenington, High-Linearity RF Amplifier Design, Norwood, MA: Artech House, 2000. [30] K. Remley, “Multisine excitation for ACPR measurements,” in IEEE MTT-S Int. Microwave Symp. Dig., Philadelphia, PA, Jun. 2003 [CD ROM], pp. 2141-2144. [31] Y. Takimoto, “Research activities on millimeter wave indoor communication systems in Japan,” 1993 IEEE MTT-S International. Microwave Symposium Digest, pp. 673-676, 1993. [32] M.F. Lei, P.Si. Wu, T.W. Huang, H. Wang, “Design and Analysis of a Miniature W-Band MMIC Subharmonically Pumped Resistive Mixer,” 2004 IEEE MTT-S Int. Microwave Sym., vol. 1, pp. 235-238, June 2004. [33] K.S. Ang, A.H. Baree, S. Nam, I.D. Robertson, “A Millimeter-wave Monolithic Sub-harmonically Pumped Resistive Mixer,” 1999 Asia Pacific Microwave Conference, Vol. 2 , pp. 222-225, December 1999. [34] WIN, Inc., 0.15µm InGaAs pHEMT Power Device Model Handbook, 2003. [35] K. Kawakami, M. Shimozawa, H. Ikematsu, K. Itoh, Y. Isota, and O. Ishida, “A millimeter-wave broadband monolithic even harmonic image rejection mixer,”1998 IEEE MTT-S Int. Microwave Sym., pp. 1443-1446, June 1998. [36] M. Yu, Robert H. Walden, A.E. Schmitz, and M. Lui, “Ka/Q-Band Doubly Balanced MMIC Mixers with Low LO Power,” IEEE Microwave and Guided Wave Letters, vol. 10, no. 10, pp. 424-426, October 2000. [37] H. Morkner, S. Kumar, and M. Vice, “A 18-45 GHz Double-Balanced Mixer with Integrated LO Amplifier and Unique Suspended Broadside-Coupled Balun,” 2003 Gallium Arsenide Integrated Circuit Symposium, pp. 267-270, November 2003. [38] C.Y. Chang, C.C. Yang, and D.C. Niu, “A Multioctave Bandwidth Rat-Race Singly Balanced Mixer,” IEEE Microwave and Guided Wave Letters, vol. 9, no. 1, pp. 37-39, January 1999. [39] Hittite mixer HMC339 datasheet. [40] P. Blount, C. Trantanella, “A High IP3, Subharmonically Pumped Mixer for LMDS Applications” 2000 Gallium Arsenide Integrated Circuit Symposium, pp. 171-174, November 2000. [41] H. Okazaki, and Y. Yamaguchi, ”Wide-Band SSB Subharmonically Pumped Mixer MMIC,” IEEE Transactions on Microwave Theory and Techniques, vol. 45, no. 12, pp. 2375-2379, December 1997. [42] Applied Wave Research, Inc. [43] Sonnet Software Inc., Sonnet User’s Manual, Release 6.0, Liverpoll, NY, Apr. 1999. [44] Maas, Stephen A, The RF and Microwave Circuit Design Cookbook, Boston: Artech House, 1998. [45] P. S. Wu, C. H. Tseng, T. W. Huang, and H. Wang, “A Singly Balanced Millimeter-wave mixer Using a Compact Transformer,” 2003 APMC Digest, vol. 3, pp. 649-652, Nov. 2003. [46] H. Morkner, S. Kumar, and M. Vice, “A 18-45 GHz Double-Balanced Mixer with Integrated LO Amplifier and Unique Suspended Broadside-Coupled Balun,” 2003 Gallium Arsenide Integrated Circuit Symposium, pp. 267-270, November 2003. [47]K. Kawakami, M. Shimozawa, H. Ikematsu, K. Itoh, Y. Isota, and O. Ishida, “A millimeter-wave broadband monolithic even harmonic image rejection mixer,”1998 IEEE MTT-S Int. Microwave Sym., pp. 1443-1446, June 1998. [48] K. S. Ang, A. H. Baree, S. Nam, and I. D. Robertson, “A millimeter-wave monolithic sub-harmonically pumped resistive mixer,” in Proc. Asia-Pacific Microwave Conf., vol. 2, pp. 222-225, 1999. [49] M. F. Lei, P. S. Wu, T. W. Huang, H. Wang, ” Design and analysis of a miniature W-band MMIC subharmonically pumped resistive mixer,” 2004 IEEE MTT-S Int. Microwave Sym., vol. 1, pp. 235-238, June 2004. [50] 陳偉阡 “諧波互調失真比與鄰近通道功率比對於寬頻訊號在微波及毫米波的相關性與應用 The correlation and application between IMR and ACPR for broadband signals in microwave and millimeter-wave frequencies” 國立台灣大學電信工程研究所博士論文, 民國94年, 2005. [51] MAXIM power amplifier MAX2247 data sheet. [52] BFG520 NPN 9 GHz wideband transistor, Philips Semiconductors. [53] S. C. Cripps, RF Power Amplifier for Wireless Communication, Norwood, MA: Artech House, 1999. [54] J. H. Tsai, H. Y. Chang, P. S. Wu, Y. L. Lee, T. W. Huang, and Wang H., “Design and Analysis of a 44-GHz MMIC Low-Loss Built-In Linearizer for High-Linearity Medium Power Amplifiers,” IEEE Transactions on Microwave Theory and Techniques, vol. 54, no.6, pp. 2487-2496, June, 2006. [55] 魏淑芬 “毫米波接收端單晶體電路之研製 Design of MMIC Components for Millimeter-Wave Receivers” 國立台灣大學電信工程研究所博士論文, 民國90年六月, 2006. [56] UE Radio Transmission and Reception (FDD), 3GPP standard TS 25.101 (V5.4.0), 2002. [57] BS Radio Transmission and Reception (FDD), 3GPP standard TS 25.104 (V3.10.0), 2002. [58] Agilent 89600 series broadband vector signal analyzer product manual.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/32526	-
dc.description.abstract	在多媒體系統和個人無線通訊系統的高度需求下，消費者對於快速以及寬頻的資訊傳送的要求也比以往都還要高，但是可利用的頻寬有限；為了有效的利用頻帶，現今的數位通訊系統使用較複雜的調變架構，但必須要使用線性度更好的收發系統。本論文主要研究於功率放大器非線性分析和毫米波非線性電路。在系統的非線性分析上，我們提出一個分析型的算式(analytical equation)來預測鄰近通道功率比(adjacent channel power ratio)。藉由量測到的交互調變失真(inter-modulation distortion ratio) 以及輸入訊號的功率密度函數(probability density function)，我們可以知道交互調變失真和鄰近通道功率比存在一個常數關係(constant correlation)，而此常數關係的差值可藉由功率密度函數來預測。此外，我們將此算式應用到毫米波系統上，即使訊號被載到毫米波頻段，常數關係的差值不會改變，只有當輸入訊號的調變方式改變，訊號的功率密度函數也跟著變的時候，常數關係的差值才會改變。在電路設計方面, 我們設計一個38到48GHz 微小型次諧波二極體混頻器和一個39到48GHz 微小型次諧波電阻式混頻器。兩顆晶片面積都只有0.72mm2。從量測結果可以印證，由於電阻式混頻器的混頻機制是線性混頻，因此比起二極體混頻器，的確有較好的線性度。	zh_TW
dc.description.abstract	Due to interests in Multi-media services and personal wireless communication systems, fast and wideband data transmission is getting demanded than ever before. However, frequency band is getting crowded as well. To utilize the limited bandwidth effectively, modern digital communication systems tend to use complex digital modulation schemes which have stringent linearity specifications for the transceivers. Power amplifier nonlinearity analysis and Millimeter-wave nonlinear circuit design and are the main research point of this thesis. We present an analytical expression to show correlation between the IM3R and the ACPR for W-CDMA signal based on PDF observation. The calculable constant correlation applies to all kinds of amplifiers and applies to distorted region above P1dB as long as the IM5R is 10dB lower than IM3R. For up-link W-CDMA, the constant correlation Co is fixed at 8 dB, while the constant Co is fixed at 2 dB for down-link W-CDMA. Besides W-CDMA, PDF influence other kinds of signals. For QPSK signal, the constant Co is 6 dB, while the constant Co is 4 dB for 16-QAM, 64-QAM and 128-QAM signals. After all the discussion and derivation for signals at microwave frequency, we apply our expression to millimeter-wave frequency band. The measured results show all the constant correlation for different modulated signals hold even if the carrier frequency is at millimeter-wave frequency, and our prediction of ACPR by IM3R measurements achieves. To conclude all the measurement and calculation, the value of constant Co does not vary with circuits, carrier frequency and channel bandwidth of signals, but does vary with modulation types of signal of different PDF. On the other hand, for circuit designs, a 38-48-GHz miniature sub-harmonically pumped diode mixer with low LO input power is presented. Quasi-lumped matching topology is employed to minimize the chip size which is 0.72mm2. Additionally, a miniature Q-band monolithic subharmonically pumped resistive mixer was developed. The compact RF/IF diplex circuit and a reduced-size balun were used to minimize the chip size which results 0.72 mm2 as well. From the measurement results, the resistive mixer has the same conversion loss as the diode mixer, but has better linearity characteristics than the diode mixer.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T04:11:18Z (GMT). No. of bitstreams: 1 ntu-95-R93942014-1.pdf: 3830082 bytes, checksum: 72d69dff5238863f6b6c6e638b5779b4 (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	CHAPTER 1 INTRODUCTION 1 1.1 Research Motives 1 1.2 Literature Survey 5 1.3 Chapter Outline 9 CHAPTER 2 NONLINEAR DISTORTION CHARACTERIZATIONS 11 2.1 Introduction 11 2.1.1 System Definition 11 2.2 Nonlinear Distortion Characterizations 12 2.2.1 One-tone Test 13 2.2.1.1 Harmonics 14 2.2.1.2 AM-AM Characterization 15 2.2.1.3 AM-PM Characterization 16 2.2.2 Two-tone Test 18 2.2.2.1 IMR Characterization 18 2.2.2.2 IP3 Characterization 20 2.2.3 Multi-tone and Digital Modulated Signal Tests 21 2.2.3.1 ACPR Characterization 22 2.2.3.2 M-IMR Characterization 23 2.3 Discussion of Magnitude and Phase Impacts on Nonlinear Figures of Merit 24 2.3.1 Phase Influence on IM3R and M-ACPR Respectively 25 2.3.2 Phase Influence on Correlation between IM3R and M-ACPR 27 CHAPTER 3 CONSTANT CORRELATION BETWEEN IM3R AND ACPR 29 3.1 Introduction 29 3.2 System Setup for Microwave Frequency Measurements 29 3.2.1 Signal Generation 30 3.2.2 Devices under Test 31 3.2.2.1 MAX2247 Power Amplifier 31 3.2.2.2 WS9901 HBT Power Amplifier 32 3.2.2.3 BFG520 1.95GHz Amplifier 34 3.3 Correlation between IM3R and ACPR in W-CDMA 36 3.3.1 IM3R and IM5R Measurements 36 3.3.2 ACPR Measurements in W-CDMA Signals 37 3.3.3 Constant Correlation in Up-link W-CDMA 40 3.3.4 Constant Correlation in Down-link W-CDMA 42 3.4 Correlation between IM3R and ACPR in QAM Signals 43 3.4.1 ACPR and IM3R Measurements in QAM Signals 43 3.5 Carrier Frequency, Channel Bandwidth and Nonlinearity Impacts on Constant Correlation 47 3.6 Observation and Conclusion 49 CHAPTER 4 EQUATION DERIVATION AND VERRIFICATION OF THE CONSTANT CORRELATION 51 4.1 Introduction 51 4.2 Constant Co Derivation for W-CDMA Signals 52 4.2.1 Time-domain Model of the W-CDMA Signal 52 4.2.2 Statistical Properties of the W-CDMA Signal 53 4.2.3 Joint Moments of the W-CDMA Signal 54 4.2.4 Analysis of W-CDMA Signal Distortion 56 4.2.5 Statistic Characterization - Probability Density Function 59 4.2.6 Analytical Equation of Constant Co for W-CDMA 60 4.2.7 Influence of Carrier Frequency on Analytical Equation 61 4.2.8 Influence of Large Input Power on Analytical Equation 62 4.3 Probability Density Function’s Impact on Constant Co for QAM Signals 63 4.4 Millimeter-wave Application 64 4.5 Conclusion 66 CHAPTER 5 SUBHARMONIC MIXER DESIGNS AT MILLIMETER-WAVE FREQUENCY 69 5.1 Introduction 69 5.1.1 Introduction to Subharmonic Mixers 70 5.1.2 0.15 um GaAs HEMT Technology 70 5.2 A 38-48-GHz Miniature MMIC Subharmonic Diode Mixer.70 5.2.1 Circuit Design 71 5.2.2 Measured Performance 73 5.3 A Q-band Miniature Monolithic Subharmonic Resistive Mixer 79 5.3.1 Circuit Design 79 5.3.2 Measured Result 82 5.4 Conclusion 85 CHAPTER 6 SUMMARY 87 6.1 Summary of the Work 87 Reference 91
dc.language.iso	en
dc.title	功率放大器非線性度分析與毫米波次諧波混頻器電路設計	zh_TW
dc.title	Power Amplifier Nonlinearity Analysis and Millimeter-wave Sub-harmonically Pumped Mixer Circuit Designs	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	王暉,陳怡然
dc.subject.keyword	次諧波混頻器,毫米波,鄰近通道功率比,	zh_TW
dc.subject.keyword	subharmonically pumped mixer,millimeter-wave,adjacent channel power ratio,	en
dc.relation.page	96
dc.rights.note	有償授權
dc.date.accepted	2006-07-26
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	電信工程學研究所	zh_TW
顯示於系所單位：	電信工程學研究所

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