Spelling suggestions: "subject:"analógicodigital converters -- design"" "subject:"analógicodigital converters -- 1design""
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Design algorithms for delta-sigma modulator loop filter topologiesKwan, Hing-kit., 關興杰. January 2008 (has links)
published_or_final_version / Electrical and Electronic Engineering / Master / Master of Philosophy
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High-resolution multi-stage time-to-digital converters. / CUHK electronic theses & dissertations collectionJanuary 2013 (has links)
在大量的實驗和應用系統中,精確的時間間隔測量是非常重要的。時間-數字轉換器 (TDC) 是一種將兩個輸入脈衝之間的到達時間差轉換成數字編碼的系統。TDC廣泛應用於高能粒子探測器、激光測距儀、數字存儲示波器與及全數字鎖相環中。由於一個TDC的性能對整個系統的性能有極大影響,它吸引了大量的相關研究。 / 現在,基於設計較為簡單,以及分辨率可自然隨工藝而進步,以時延元件方式實現的TDC大大多於以密集模擬電路方式實現的TDC。不過,設計基於時延線的高分辨率TDC時也面對一定挑戰。首先,當TDC的動態範圍增加,時延單元(基本時間測量單元)的數目將呈指數增長,這大大增加了功耗。更糟的是,當時延單元增加時,每個單元中電路噪聲和不匹配引起的線性誤差會沿時延線積累,使TDC的分辨率變差和線性誤差變大。此外,因為制程限制了時延單元最低時延,所以TDC可達到的最低步長亦受此限制。雖然先前有其他研究提出一系列方法超越制程限制以提高時間分辨率,但是它們也有一些不足,例如時延單元數量需要大大增加。 / 在這篇論文中,我們專注於設計高分辨率的TDC。首先,為了減小在TDC中時延元件的數目,我們提出一個基於威尼爾-並行時延線 (Vernier Parallel Delay Line) 的兩段TDC。我們提出通過串聯兩組分辨率略有差異的平行時延線,以致整個TDC的分辨率比當中任何一組的更好。在這樣的配置下,因為首級時延線同時成為第一級TDC,所以時延元件的數目,相比單級TDC所需的大大降低。此外,VPDL令致兩組時延線的延遲步長接近,從而降低時延單元的時延要求,而同一個時延元件設計也可用在兩級的TDC中,以簡化電路設計。 / 第二,為了改善VPDL TDC中的線性誤差和偏移問題,我們提出了一個校準方案。這個校準方案是通過改變時延單元成為可調步長單元,以形成一個數字反饋迴路以調整時延/測量TDC中每步的步長,然後根據該信息調整作校準。這個方案中,時延單元既用作調整時延,也作為校準的參考,所以沒有需要從外部輸入/內部產生準確的定時信號。這簡化了校準過程。 / 第三,我們提出了一個建模方法,以提供一個加快系統設計和功能驗證的方法。這個建模方法把每個時鐘週期輸入的時間差轉換成實數,使在直接建模方法中存在的精度和仿真步長間權衡問題、建模問題和校準邏輯的瞬態仿真問題得以緩解。 / 最後,我們以UMC 0.13μm CMOS工藝製造了一個6位元的VPDL TDC原型。實驗結果證明這原型實現了5ps的分辨率, 0.6LSB的DNL和0.4LSB的單次測量精度。 / Precise time interval measurement is very important in many experimental and applied systems. Time-to-digital converters (TDC) are one type of such measurement systems, which convert the arrival time difference between two input pulses into digital codes. TDCs find various applications in high energy particle detectors, laser range finders, digital storage oscilloscopes, also in all-digital phase lock loops. Since the performance of a TDC greatly affects the performance of the overall system, it attracts a great deal of research efforts. / TDCs based on delay elements are currently dominant compared to other analog-circuit-intensive implementations, because of their design simplicity and that their resolution is inherently enhanced by technology advancement. However, there are challenges on designing high-resolution delay-line-based TDCs. First, when the full scale of the TDC is increased, the number of delay cells (basic time measurement units) have to be increased exponentially, which greatly increases the power consumption. Even worse, when the number of delay cells increases, circuit noises and mismatch-induced nonlinearity from each cell accumulate along the chain and worsen the resolution and linearity of the TDC. Besides, the achievable finest resolution (i.e., the least significant bit, LSB) of the delay-line-based TDCs is limited by the minimum delay of the delay cells, which is process-dependent. Although a number of methods are proposed previously to improve the time resolution beyond the process restriction, there are shortcomings on those architectures, for example, the increase of delay elements needed for generating refined time reference. / In this thesis, we focus on the design of high resolution TDCs. First, to decrease the number of delay elements in the TDC, a two-stage Vernier Parallel Delay Line (VPDL) based TDC is proposed. By cascading two sets of parallel delay lines with slightly difference in resolution, the overall resolution of the TDC is much finer than that of the two sets. By using the first stage delay line as the time reference of the coarse TDC, the number of delay elements is greatly reduced when compared to single stage ones. Besides that, the VPDL makes the delay step sizes similar between stages utilizing Vernier principle, which relaxes the step size requirement of the delay elements, also facilitating design re-use of delay cells among two stages. / Second, to improve the linearity and offset problems in the proposed TDC architecture, a foreground calibration scheme is proposed. By making the delay cells discretely-tunable with equal step, a digital feedback loop can be formed to tune the delay/ measure the step size of each step, then tune the delay of each cell according to the information. The proposed scheme uses the discretely-tunable delay steps to tune the delay, also as the reference of calibration, so no accurate timing signal is needed from internal/external of the TDC. This simplifies the calibration process. / Third, a behavioral modeling approach is proposed to provide a quick way for system design and functional verification. The proposed modeling approach transforms the input time difference at each clock cycle into amplitude, so that the tradeoff between accuracy and simulation step size, problems on modeling and transient simulation of calibration logic that exist in direct modeling approach are alleviated. / To prove the proposed techniques, a 6-bit prototype TDC is fabricated in a 0.13μm CMOS technology, achieving a LSB of 5ps, DNL of 0.6LSB and single-shot precision of 0.4LSB in measurement. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Detailed summary in vernacular field only. / Ko, Chi Tung. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2013. / Includes bibliographical references. / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstracts in also in Chinese. / Abstract --- p.i / 摘要 --- p.iv / Acknowledgements --- p.vi / Table of Contents --- p.viii / List of Figures --- p.xii / List of Tables --- p.xvii / Chapter Chapter 1 --- Introduction --- p.1 / Chapter 1.1 --- What is TDC and Applications of TDCs --- p.1 / Chapter 1.2 --- Objectives of This Research --- p.4 / Chapter 1.3 --- Original Contributions --- p.4 / Chapter 1.4 --- Organization of Thesis --- p.5 / REFERENCES --- p.6 / Chapter Chapter 2 --- Fundamentals of TDCs --- p.8 / Chapter 2.1 --- Performance Measures --- p.8 / Chapter 2.1.1 --- Step Size --- p.8 / Chapter 2.1.2 --- Single-shot Precision --- p.9 / Chapter 2.1.3 --- Dynamic Range (DR) --- p.9 / Chapter 2.1.4 --- Linearity --- p.9 / Chapter 2.1.4.1 --- Differential Non-linearity (DNL) --- p.9 / Chapter 2.1.4.2 --- Integral Non-linearity (INL) --- p.10 / Chapter 2.2 --- Types of TDCs --- p.11 / Chapter 2.2.1 --- Analog Method --- p.12 / Chapter 2.2.1.1 --- Time-to-amplitude Converter and ADC [2-6], [2-8] --- p.12 / Chapter 2.2.2 --- Digital Methods --- p.13 / Chapter 2.2.2.1 --- Counters --- p.13 / Chapter 2.2.2.2 --- Delay Line --- p.15 / Chapter 2.2.2.3 --- Vernier Delay Line --- p.16 / Chapter 2.2.2.4 --- Parallel Delay Line --- p.18 / Chapter 2.2.2.5 --- Gated-ring Oscillator (GRO) --- p.20 / Chapter 2.2.2.6 --- Time Amplifier --- p.21 / Chapter 2.3 --- TDC Architecture: Multi-stage vs Single stage TDC --- p.23 / Chapter 2.4 --- Summary --- p.25 / REFERENCES --- p.26 / Chapter Chapter 3 --- Two-stage Vernier Parallel Delay Line (VPDL) TDC with DNL and Offset Calibration --- p.28 / Chapter 3.1 --- Proposed TDC Architecture - Vernier Parallel Delay Line (VPDL) --- p.28 / Chapter 3.2 --- Advantages and Limitation of VPDL TDC --- p.32 / Chapter 3.3 --- Latch buffer --- p.33 / Chapter 3.4 --- Offset and DNL Problems of VPDL TDC --- p.34 / Chapter 3.4.1 --- Latch Buffer Offset --- p.35 / Chapter 3.4.2 --- Latch Offset --- p.37 / Chapter 3.4.3 --- Delay Element Offset --- p.39 / Chapter 3.5 --- Proposed Offset and DNL Calibration Scheme --- p.42 / Chapter 3.5.1 --- Offset Calibration --- p.42 / Chapter 3.5.2 --- DNL Calibration --- p.45 / Chapter 3.5.3 --- Digital Error Correction --- p.51 / REFERENCES --- p.56 / Chapter Chapter 4 --- Behavioral Modeling and System Design of TDC --- p.57 / Chapter 4.1 --- TDC Behavioral Modeling --- p.57 / Chapter 4.1.1 --- Direct Modeling Approach --- p.57 / Chapter 4.1.1.1 --- Modeling of Circuit Blocks --- p.58 / Chapter 4.1.1.2 --- Limitations of Direct Modeling Approach --- p.60 / Chapter 4.1.2 --- Proposed Modeling Approach --- p.61 / Chapter 4.1.2.1 --- Transformation of Time Delay --- p.62 / Chapter 4.1.2.2 --- Modeling of Different Circuit Blocks --- p.64 / Chapter 4.1.2.2.1 --- Delay Cells --- p.64 / Chapter 4.1.2.2.2 --- Sampling Latches --- p.66 / Chapter 4.1.2.2.3 --- DTC --- p.68 / Chapter 4.1.2.2.4 --- Calibration Logic --- p.69 / Chapter 4.1.2.3 --- Limitation on the Proposed Approach --- p.72 / Chapter 4.2 --- System Overview of TDC --- p.73 / Chapter 4.2.1 --- Circuit Block Specifications --- p.77 / Chapter 4.2.1.1 --- Calibration Step Sizes --- p.77 / Chapter 4.2.1.2 --- Effect of Latch Offset Mismatch --- p.80 / Chapter 4.2.1.3 --- Effect of Calibration Step Size Mismatches --- p.86 / Chapter 4.3 --- Summary --- p.89 / REFERENCES --- p.89 / Chapter Chapter 5 --- Circuit Implementation and Simulation Results of the TDC --- p.91 / Chapter 5.1.1 --- Sampling Latch --- p.91 / Chapter 5.1.2 --- Delay Cells --- p.95 / Chapter 5.1.2.1 --- Comparison of Jitter between Differential Pair and Single-ended Delay Line --- p.95 / Chapter 5.1.2.2 --- Circuit Design --- p.103 / Chapter 5.1.3 --- Residue Routing Switch --- p.107 / Chapter 5.2 --- Transistor-level Simulation Results --- p.109 / Chapter 5.3 --- Summary --- p.114 / REFERENCES --- p.114 / Chapter Chapter 6 --- Physical Design and Experimental Results of the TDC --- p.117 / Chapter 6.1 --- Physical Design of TDC --- p.117 / Chapter 6.1.1 --- Floor Planning --- p.117 / Chapter 6.1.2 --- Delay Cell --- p.120 / Chapter 6.2 --- Experimental Results --- p.123 / Chapter 6.2.1 --- Measurement Setup --- p.123 / Chapter 6.2.2 --- Calibration Procedure --- p.126 / Chapter 6.2.3 --- Measurement Procedure --- p.130 / Chapter 6.2.4 --- Measurement Results --- p.130 / Chapter 6.2.4.1 --- TDC1 Measurement --- p.131 / Chapter 6.2.4.2 --- Overall TDC Measurement --- p.133 / Chapter 6.3 --- Summary --- p.141 / REFERENCES --- p.144 / Chapter Chapter 7 --- Conclusions and Future Works --- p.146 / Chapter 7.1 --- Conclusions --- p.146 / Chapter 7.2 --- Future Works --- p.147
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An IF input continuous-time sigma-delta analog-digital converter with high image rejection.January 2004 (has links)
Shen Jun-Hua. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2004. / Includes bibliographical references (leaves 151-154). / Abstracts in English and Chinese. / Abstract --- p.ii / 摘要 --- p.iv / Acknowledgments --- p.vi / Table of Contents --- p.vii / List of Figures --- p.ix / List of Tables --- p.xii / Chapter Chapter 1 --- Introduction --- p.1 / Chapter 1.1. --- Overview --- p.1 / Chapter 1.2. --- Motivation and Objectives --- p.5 / Chapter 1.3. --- Original Contributions of This Work --- p.6 / Chapter 1.4. --- Organization of the Thesis --- p.7 / Chapter Chapter 2 --- Sigma-delta Modulation and IF A/D Conversion --- p.8 / Chapter 2.1. --- Introduction --- p.8 / Chapter 2.2. --- Fundamentals of Sigma-delta Modulation --- p.9 / Chapter 2.2.1. --- Feedback Controlled System --- p.9 / Chapter 2.2.2. --- Quantization Noise --- p.11 / Chapter 2.2.3. --- Oversampling and Noise-shaping --- p.11 / Chapter 2.2.4. --- Stability --- p.15 / Chapter 2.2.5. --- Noise Sources --- p.17 / Chapter 2.2.6. --- Baseband Sigma-delta Modulation --- p.28 / Chapter 2.2.7. --- Bandpass Sigma-delta Modulation --- p.28 / Chapter 2.3. --- Discrete-time Sigma-delta Modulation --- p.29 / Chapter 2.4. --- Continuous-time Sigma-delta Modulation --- p.29 / Chapter 2.5. --- IF-input Complex Analog to Digital Converter --- p.31 / Chapter 2.6. --- Image Rejection --- p.32 / Chapter 2.7. --- Integrated Mixer --- p.36 / Chapter Chapter 3 --- High Level Modeling and Simulation --- p.39 / Chapter 3.1. --- Introduction --- p.39 / Chapter 3.2. --- System Level Sigma-delta Modulator Design --- p.40 / Chapter 3.3. --- Continuous-time NTF Generation --- p.46 / Chapter 3.4. --- Discrete-time Sigma-delta Modulator Modeling --- p.50 / Chapter 3.5. --- Continuous-time Sigma-delta Modulator Modeling --- p.52 / Chapter 3.6. --- Modeling of Nonidealities --- p.53 / Chapter 3.7. --- High Level Simulation Results --- p.58 / Chapter Chapter 4 --- Transistor Level Implementation of the Complex Modulator and Layout --- p.65 / Chapter 4.1. --- Introduction --- p.65 / Chapter 4.2. --- IF Input Complex Modulator --- p.65 / Chapter 4.3. --- High IR IF Input Complex Modulator Design --- p.67 / Chapter 4.4. --- System Design --- p.73 / Chapter 4.5. --- Building Blocks Design --- p.77 / Chapter 4.5.1. --- Transconductor Design --- p.77 / Chapter 4.5.2. --- RC Integrator Design --- p.87 / Chapter 4.5.3. --- Gm-C Integrator Design --- p.90 / Chapter 4.5.4. --- Voltage to Current Converter --- p.95 / Chapter 4.5.5. --- Current Comparator Design --- p.96 / Chapter 4.5.6. --- Dynamic Element Matching Design --- p.98 / Chapter 4.5.7. --- Mixer Design --- p.100 / Chapter 4.5.8. --- Clock Generator --- p.103 / Chapter 4.6. --- Transistor Level Simulation of the Design --- p.106 / Chapter 4.7. --- Layout of the Mixed Signal Design --- p.109 / Chapter 4.7.1. --- Layout Overview --- p.109 / Chapter 4.7.2. --- Capacitor layout --- p.110 / Chapter 4.7.3. --- Resistor Layout --- p.113 / Chapter 4.7.4. --- Power and Ground Routing --- p.114 / Chapter 4.7.5. --- OTA Layout --- p.115 / Chapter 4.7.6. --- Chip Layout --- p.117 / Chapter 4.8. --- PostLayout Simulation --- p.120 / Chapter 5. --- Chapter 5 Measurement Results and Improvement --- p.122 / Chapter 5.1. --- Introduction --- p.122 / Chapter 5.2. --- PCB Design --- p.123 / Chapter 5.3. --- Test Setup --- p.125 / Chapter 5.4. --- Measurement of SNR and IRR --- p.128 / Chapter 5.5. --- Discussion of the Chip Performance --- p.131 / Chapter 5.6. --- Design of Robust Sigma Delta Modulator --- p.139 / Chapter Chapter 6 --- Conclusion --- p.148 / Chapter 6.1. --- Conclusion --- p.148 / Chapter 6.2. --- Future Work --- p.150 / Bibliography --- p.151 / Appendix A Schematics of Building Blocks --- p.155 / Author's Publications --- p.157
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Aspects of designing a high speed analog to digital converterHsu, M. S. (Ming Shau) January 1992 (has links) (PDF)
Bibliography: leaves 212-223.
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Design of a 1.8-V 14-bit [delta] - [sigma] A/D converter with 8X oversampling and 4 MHz Nyquist output rateJiang, Ruoxin 30 July 2001 (has links)
In this dissertation, a new ����� A/D converter is presented that is ideally
suited for communication applications. It is based on a single-loop single-stage
structure, which can realize a high maximum out-of-band quantization noise gain
while maintaining stable operation and thus achieve 14-bit resolution at 8 times
oversampling. A fifth-order ����� analog-to-digital converter (A/D) has been designed
and tested in a 0.18 ��m CMOS process. This is the first single-stage �����
A/D converter reported in the literature that achieves 14-bit resolution at 4 MHz
equivalent Nyquist rate with a 1.8-V power supply. / Graduation date: 2002
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A 1-m W, 14-bit [sigma] [delta] A/D converter with 10-KHz conversion rateGupta, Shivani 24 February 1995 (has links)
Graduation date: 1995
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Some considerations in the design of a low-power, 15-bit, analog-to-digital converterRagsdale, Charles R. January 1984 (has links)
Call number: LD2668 .T4 1984 R33 / Master of Science
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CMOS current mode A/D converter with improved power efficiency using current mirror memory cells.January 2004 (has links)
Chi-Hong, Chan. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2004. / Includes bibliographical references (leaves 114-117). / Abstracts in English and Chinese. / Abstract --- p.i / 摘要 --- p.iii / Acknowledgements --- p.iv / Table of Contents --- p.vi / List of Figures --- p.x / List of Tables --- p.xiii / Chapter 1. --- Introduction --- p.1 / Chapter 1.1. --- System on a Chip (SoC) Design Challenges --- p.1 / Chapter 1.2. --- Research Objective --- p.3 / Chapter 1.3. --- Thesis Organization --- p.3 / Chapter 2. --- Fundamentals of CMOS Current Mode A/D converters --- p.5 / Chapter 2.1. --- Overview --- p.5 / Chapter 2.2. --- Current Mode Signal Processing --- p.5 / Chapter 2.2.1. --- Voltage Mode Circuit Design Technique --- p.5 / Chapter 2.2.2. --- Current Mode Circuit Design Technique --- p.6 / Chapter 2.2.3. --- First Generation (FG) SI Memory Cell vs. Second Generation (SG) SI Memory Cell --- p.7 / Chapter 2.3. --- Ideal Nyquist Rate A/D converters --- p.9 / Chapter 2.4. --- Static Performance Parameters --- p.13 / Chapter 2.4.1. --- Differential Non-Linearity (DNL) --- p.13 / Chapter 2.4.2. --- Integral Non-Linearity (INL) --- p.13 / Chapter 2.5. --- Performance Parameters in Frequency Domain --- p.15 / Chapter 2.5.1. --- Signal-to-Noise and Distortion Ratio (SNDR) --- p.16 / Chapter 2.5.2. --- Effective Number of Bits (ENOB) --- p.16 / Chapter 2.5.3. --- Spurious Free Dynamic Range (SFDR) --- p.16 / Chapter 3. --- Proposed Current Mirror Memory Cell (CMMC) --- p.18 / Chapter 3.1. --- Overview --- p.18 / Chapter 3.2. --- Working Principle of CMMC --- p.18 / Chapter 3.3. --- CMMC vs. FG SI Cells --- p.20 / Chapter 3.4. --- Analog Delay Cell Implementation using the two kinds of memory cells --- p.21 / Chapter 3.4.1. --- Delay Cell Implementation by FG Memory Cells --- p.22 / Chapter 3.4.2. --- Delay Cell Implementation by CMMC --- p.23 / Chapter 3.4.3. --- Simulation Results --- p.24 / Chapter 3.5. --- Conclusion --- p.27 / Chapter 4. --- Architectural Design of the 12-Bit CMOS A/D Converter --- p.28 / Chapter 4.1. --- Overview --- p.28 / Chapter 4.2. --- The Floating Analog-to-Digital Converter --- p.28 / Chapter 4.3. --- Conversion Algorithm --- p.32 / Chapter 4.4. --- Accuracy Considerations Due to Circuit Non-Idealities --- p.34 / Chapter 4.4.1. --- Gain Error of Residual Generator --- p.34 / Chapter 4.4.2. --- Offset Error of Residual Generator --- p.36 / Chapter 4.5. --- Speed Consideration --- p.36 / Chapter 4.6. --- Power Consumption vs. No. of Bits per Stage --- p.38 / Chapter 4.7. --- Final Architectural Design --- p.40 / Chapter 5. --- A/D Converter Implementation using CMMC --- p.41 / Chapter 5.1. --- Overview --- p.41 / Chapter 5.2. --- Current Sample-and-Hold --- p.41 / Chapter 5.2.1. --- Signal Independent CFT Cancellation --- p.43 / Chapter 5.2.2. --- Signal Dependent CFT Cancellation --- p.44 / Chapter 5.2.3. --- Complete CFT Cancellation --- p.45 / Chapter 5.2.4. --- CFT Cancellation by Transmission Gate --- p.45 / Chapter 5.2.5. --- CFT Cancellation by Dummy Switches --- p.47 / Chapter 5.3. --- Common Mode Feed Forward (CMFF) --- p.48 / Chapter 5.4. --- Differential Current Comparator --- p.52 / Chapter 5.4.1. --- Regenerative Latch --- p.53 / Chapter 5.4.2. --- Pre-amplifier --- p.54 / Chapter 5.5. --- Residual Generator --- p.55 / Chapter 5.6. --- Thermometer to Binary code Decoder --- p.57 / Chapter 6. --- Layout Considerations --- p.59 / Chapter 6.1. --- Overview --- p.59 / Chapter 6.2. --- Process Introduction --- p.59 / Chapter 6.3. --- Common Centroid Layout --- p.60 / Chapter 6.4. --- The Design of Power Supply Rails --- p.63 / Chapter 6.5. --- Shielding --- p.64 / Chapter 6.6. --- Layout of the whole design --- p.65 / Chapter 7. --- Simulation Results --- p.67 / Chapter 7.1. --- Overview --- p.67 / Chapter 7.2. --- Simulation Results of the Current Sample-and-Hold --- p.67 / Chapter 7.3. --- Simulation Results of the Differential Current Comparator --- p.70 / Chapter 7.4. --- Simulation Results of the overall ADC using One-Stage Simulation Result --- p.71 / Chapter 7.5. --- Power Simulation of the Overall 12-Bit ADC --- p.75 / Chapter 7.6. --- Summary --- p.78 / Chapter 8. --- Measurement Results --- p.79 / Chapter 8.1. --- Overview --- p.79 / Chapter 8.2. --- PCB Design Consideration --- p.79 / Chapter 8.3. --- Measurement Setup --- p.82 / Chapter 8.4. --- Measurement Result --- p.84 / Chapter 8.4.1. --- Static Parameters --- p.84 / Chapter 8.4.2. --- Frequency Domain Measures --- p.85 / Chapter 8.5. --- Discussion --- p.90 / Chapter 9. --- Conclusion --- p.95 / Chapter 9.1. --- Research Methodology of this Project --- p.95 / Chapter 9.2. --- Comparison between Voltage Mode and Current Mode Circuit --- p.97 / Chapter 9.3. --- Contribution of this Project --- p.98 / Chapter A. --- Appendices --- p.99 / Chapter A.I. --- Small Signal Analysis on CMMC and FG Memory Cell --- p.99 / Chapter A.II. --- The ESD Protection on the ADC --- p.102 / Chapter A.III. --- The Histogram Test to determine the DNL and INL of ADC --- p.104 / Chapter A.IV. --- Measurement Result of a Commercially Available ADC AD7820 --- p.106 / Chapter A.V. --- Pin Assignment of the Current Mode ADC --- p.109 / Chapter A.VI. --- Schematics of the Current Mode ADC --- p.111 / Chapter A.VII. --- The Chip Micrograph --- p.113 / Bibliography --- p.114
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An IF-sampling switched capacitor complex lowpass sigma delta modulator with high image rejection.January 2004 (has links)
by Cheng Wang-tung. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2004. / Includes bibliographical references (leaves 97-99). / Abstracts in English and Chinese. / Abstract --- p.i / 摘要 --- p.i / Acknowledgements --- p.ii / Table of Contents --- p.iii / List of Figures --- p.vii / List of Tables --- p.xi / Chapter Chapter 1 --- Introduction --- p.1 / Chapter 1.1 --- Motivations --- p.1 / Chapter 1.2 --- Objective --- p.4 / Chapter 1.3 --- Outline --- p.4 / Chapter Chapter 2 --- Quadrature ΣΔ Modulator for A/D Conversion --- p.5 / Chapter 2.1 --- Introduction --- p.5 / Chapter 2.2 --- Oversampling ΣΔ Converter --- p.6 / Chapter 2.3 --- Theory of ΣΔ modulation --- p.6 / Chapter 2.3.1 --- Quantization noise --- p.7 / Chapter 2.3.2 --- Oversampling --- p.8 / Chapter 2.3.3 --- Noise Shaping --- p.9 / Chapter 2.3.4 --- Performance Parameter --- p.11 / Chapter 2.3.5 --- Circuit Design of ΣΔ modulator --- p.11 / Chapter 2.3.6 --- Case Study --- p.12 / Chapter 2.3.6.1 --- Transfer Function --- p.12 / Chapter 2.3.6.2 --- Noise Analysis of First Order ΣΔ Modulator --- p.13 / Chapter 2.3.6.3 --- Circuit Level Implementation: --- p.14 / Chapter 2.4 --- Choice of Architecture: Lowpass or Bandpass? --- p.15 / Chapter 2.5 --- I/Q Modulation and Image Rejection --- p.18 / Chapter 2.5.1 --- Quadrature signal --- p.18 / Chapter 2.5.2 --- I/Q Modulation --- p.19 / Chapter 2.6 --- Image Rejection in SC ΣΔ Complex Topology --- p.21 / Chapter 2.6.1 --- High Level Simulation --- p.23 / Chapter 2.6.2 --- Discussion --- p.26 / Chapter 2.7 --- Summary --- p.27 / Chapter Chapter 3 --- Capacitor Sharing Architecture --- p.28 / Chapter 3.1 --- Introduction --- p.28 / Chapter 3.2 --- Proposed mismatch free SC complex ΣΔ Modulator --- p.28 / Chapter 3.2.1 --- Principle of Operation --- p.30 / Chapter 3.3 --- Justification of the Proposed Idea --- p.35 / Chapter 3.4 --- Summary --- p.37 / Chapter Chapter 4 --- Transistor Level Circuit Design --- p.39 / Chapter 4.1 --- Introduction --- p.39 / Chapter 4.2 --- Design of ΣΔ Modulator --- p.39 / Chapter 4.2.1 --- Specification of ΣΔ Modulator --- p.40 / Chapter 4.3 --- Design of Operational Amplifier --- p.45 / Chapter 4.3.1 --- Folded-cascode Operational Amplifier --- p.45 / Chapter 4.3.2 --- Common Mode feedback --- p.47 / Chapter 4.3.3 --- Bias Circuit --- p.49 / Chapter 4.3.4 --- Simulation Results --- p.50 / Chapter 4.4 --- Design of Comparator --- p.54 / Chapter 4.4.1 --- Regenerative Feedback Comparator --- p.54 / Chapter 4.4.2 --- Simulation Results --- p.55 / Chapter 4.5 --- Design of Clock Generator --- p.56 / Chapter 4.5.1 --- Non-Overlapping clock generation --- p.57 / Chapter 4.5.2 --- Simulation Results --- p.58 / Chapter 4.6 --- Simulation Results of ΣΔ Modulator --- p.59 / Chapter 4.7 --- Simulation Results --- p.61 / Chapter 4.7.1 --- Proposed Architecture --- p.62 / Chapter 4.7.2 --- Traditional Architecture --- p.62 / Chapter 4.8 --- Summary --- p.63 / Chapter Chapter 5 --- Layout Considerations and Post-Layout Simulation --- p.65 / Chapter 5.1 --- Introduction --- p.65 / Chapter 5.2 --- Common-Centroid Structure --- p.65 / Chapter 5.3 --- Shielding Technique --- p.67 / Chapter 5.3.1 --- Shielding of device by substrate --- p.67 / Chapter 5.3.2 --- Floor Planning --- p.68 / Chapter 5.4 --- Layout of Power Rail --- p.69 / Chapter 5.5 --- Layout and Post-Layout Simulation of OpAmp --- p.70 / Chapter 5.6 --- Layout and Post-Layout Simulation --- p.74 / Chapter 5.6.1 --- Proposed Architecture --- p.75 / Chapter 5.6.2 --- Traditional Architecture --- p.77 / Chapter 5.7 --- Summary --- p.79 / Chapter Chapter 6 --- Measurement Results --- p.81 / Chapter 6.1 --- Introduction --- p.81 / Chapter 6.2 --- Considerations of PCB Design --- p.82 / Chapter 6.3 --- Measurement Setup --- p.83 / Chapter 6.4 --- Measurement Results --- p.85 / Chapter 6.4.1 --- Measurement Results of Proposed Architecture --- p.85 / Chapter 6.5 --- Summary --- p.92 / Chapter Chapter 7 --- Conclusion --- p.95 / Chapter 7.1 --- Conclusion --- p.95 / Chapter 7.2 --- Future Works --- p.96 / References --- p.97 / Appendix --- p.100 / Chapter A.1 --- Publications --- p.100 / Chapter A.2 --- Schematic of proposed front end --- p.101 / Chapter A.3 --- Schematic of SC ΣΔ modulator --- p.102 / Chapter A.4 --- Schematic of the folded-cascode amplifier --- p.103 / Chapter A.5 --- Schematic of biasing circuit --- p.104 / Chapter A.6 --- Schematic of preamplifier in comparator --- p.105 / Chapter A.7 --- Schematic of latched part in comparator --- p.106 / Chapter A.8 --- Schematic of the clock generator --- p.107
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Accuracy enhancement techniques in low-voltage high-speed pipelined ADC designLi, Jipeng 03 October 2003 (has links)
Pipelined analog to digital converters (ADCs) are very important building
blocks in many electronic systems such as high quality video systems, high
performance digital communication systems and high speed data acquisition systems.
The rapid development of these applications is driving the design of pipeline ADCs
towards higher speed, higher dynamic range, lower power consumption and lower
power supply voltage with the CMOS technology scaling. This trend poses great
challenges to conventional pipelined ADC designs which rely on high-gain
operational amplifiers (opamps) and well matched capacitors to achieve high accuracy. In this thesis, two novel accuracy improvement techniques to overcome the
accuracy limit set by analog building blocks (opamps and capacitors) in the context of
low-voltage and high-speed pipelined ADC design are presented. One is the time-shifted
correlated double sampling (CDS) technique which addresses the finite opamp
gain effect and the other is the radix-based background digital calibration technique
which can take care of both finite opamp gain and capacitor mismatch. These methods
are simple, easy to implement and power efficient. The effectiveness of the proposed
techniques is demonstrated in simulation as well as in experiment.
Two prototype ADCs have been designed and fabricated in 0.18μm CMOS
technology as the experimental verification of the proposed techniques. The first ADC
is a 1.8V 10-bit pipeline ADC which incorporated the time-shifted CDS technique to
boost the effective gain of the amplifiers. Much better gain-bandwidth tradeoff in
amplifier design is achieved with this gain boosting. Measurement results show total
power consumption of 67mW at 1.8V when operating at 100MSPS. The SNR, SNDR
and SFDR are 55dB, 54dB and 65dB respectively given a 1MHz input signal. The
second one is a 0.9V 12-bit two-stage cyclic ADC which employed a novel
correlation-based background calibration to enhance the linearity. The linearity limit
set by the capacitor mismatches, finite opamp gain effects is exceeded. After
calibration, the SFDR is improved by about 33dB and exceeds 80dB. The power
consumption is 12mW from 0.9V supply when operating at 2MSPS. / Graduation date: 2004
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