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研究生: 戴子鈞
Dai, Zih-Jyun
論文名稱: 應用於高速電路之靜電放電防護設計
ESD Protection Design of High-Speed Circuit
指導教授: 林群祐
Lin, Chun-Yu
口試委員: 柯明道
Ker, Ming-Dou
張勝良
Jang, Sheng-Lyang
林群祐
Lin, Chun-Yu
口試日期: 2021/10/22
學位類別: 碩士
Master
系所名稱: 電機工程學系
Department of Electrical Engineering
論文出版年: 2021
畢業學年度: 109
語文別: 英文
論文頁數: 98
中文關鍵詞: 全晶片靜電放電防護π型架構轉阻放大器
英文關鍵詞: whole-chip ESD protection, π-structure, TIA
DOI URL: http://doi.org/10.6345/NTNU202101807
論文種類: 學術論文
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  • 本論文旨在研究應用於高速積體電路之全晶片靜電放電防護設計,在CMOS製程下實作,以低電容元件搭配分散式電路的設計,並與既有二極體及電晶體元件的設計相比較。
    隨著內部電路的操作頻率不斷提升,寄生電容造成的訊號損耗嚴重影響電路高頻性能,本篇論文利用兩級分散式電路架構的方式,將單級的防護元件以小尺寸分散至兩級來設計防護電路,以降低每級的元件寄生電容,並在兩級之間以匹配元件降低訊號通過時的損耗,形成π型架構的設計。傳統的π型架構設計使用的是二極體或電晶體元件,本論文提出利用其他低電容矽控整流器元件如堆疊二極體內嵌矽控整流器 (SDSCR) 及電阻觸發式矽控整流器 (RTSCR) 搭配π型架構,組成π-SDSCR與π-RTSCR,來與π型連接的傳統元件進行比較。由實驗結果可知,在20GHz時,創新設計π-SDSCR在單位插入損耗 (S21) 下所達到的二次崩潰電流 (It2) 為傳統設計的1.76倍,π-RTSCR則為傳統設計的1.62倍,相較於傳統架構,本文提出的設計具備更高的ESD防護能力及更低的寄生電容,更適用於高速電路。
    最後,為了驗證與比較防護電路的性能,本論文也設計了一應用於高速的轉阻放大器 (Trans-impedance amplifier, TIA),分別搭配傳統π型二極體設計與本論文所提出的防護電路,並進行電路的量測,驗證實際的防護效果及對電路性能的影響。由實驗結果可知,創新設計與傳統設計都能為TIA電路提供4kV的HBM ESD 耐受度,且π-SDSCR在17GHz時的插入損耗僅傳統設計的0.83倍,π-RTSCR則為傳統設計的0.9倍,顯示創新設計在提供足夠ESD耐受度的同時,對電路高頻性能影響更低。

    This thesis is to study a whole-chip electrostatic discharge (ESD) protection design for high-speed circuits. In CMOS process, the low-capacitance device is designed with distributed circuit in comparison with traditional design by diode and MOS.
    As the operating frequency of the internal circuit increases, the signal loss caused by parasitic capacitance seriously affects the high-frequency performance of the circuit. A two-stage distributed circuit architecture is used in this thesis to divide a single-stage protection device into two stages in a small size which can reduce the parasitic capacitance of the device in each stage. The matching element is added between two stages and formed π-structure to reduce the signal loss. Diode or MOS is used in traditional π-model design. This thesis proposes to use other innovative low-capacitance silicon-controlled rectifier (SCR) such as stacked diodes with embedded silicon-controlled rectifier (SDSCR) and resistor-triggered SCR (RTSCR) with the π-model to compare with the π-connected traditional devices. From the experiment result, the secondary breakdown current (It2) provided by proposed π-SDSCR per unit insertion loss (S21) at 20GHz is 1.76 times higher than that of the traditional design. That value provided by proposed π-RTSCR is 1.62 times higher than that of the traditional design. As compare with traditional structure, proposed designs have higher ESD protection ability and lower parasitic capacitance which are more suitable for high-speed circuits.
    In order to verify and compare the performance of the protection circuits, this thesis designed a high-speed trans-impedance amplifier (TIA), which has added the traditional π-diode and the proposed π-SCR in this paper as ESD protection. The circuits were measured to verify the protection ability and the influence on the circuit performance. From the experiment result, both traditional and proposed designs provide 4kV HBM ESD robustness for the TIA circuit. However, the degradation of insertion loss (ΔS21) of TIA with π-SDSCR at 17GHz is only 0.83 times of that of TIA with traditional design. The value of TIA with π-RTSCR is 0.9 times of that of TIA with traditional design. It shows that as compare with traditional structure, proposed designs have lower impact on the high frequency performance of the circuit, while also providing sufficient ESD tolerance.

    Acknowledgement i Abstract (Chinese) ii Abstract (English) iv Contents vi List of Tables viii List of Figures ix Chapter 1 Introduction 1 1.1 Motivation 1 1.2 Background of ESD 2 1.3 ESD Test Standards 2 1.4 Design Concepts of ESD Protection 5 1.5 Organization of This Thesis 7 Chapter 2 Studies of ESD Protection Designs for High-Speed Applications 8 2.1 Consideration of ESD Protection Design at High-Speed circuits 8 2.2 ESD Protection Designs for High-Speed Application 11 2.2.1 Capacitive ESD Protection Circuit 11 2.2.2 Distributed ESD Protection Circuit (DESD) 14 Chapter 3 Design of π-Model SCR π-SCR) 16 3.1 Design Concepts of Distributed Circuit 16 3.2 Traditional π-Model Diode (π-Diode) 18 3.3 Traditional π-Model MOS (π-MOS) 22 3.4 Proposed π-Model SCR (π-SCR) 26 3.4.1 π-Model SDSCR (π-SDSCR) 29 3.4.2 π-Model RTSCR (π-RTSCR) 33 3.5 Simulation Results 37 3.6 Measurement Results 41 3.6.1 High-Frequency Performance 42 3.6.2 TLP I-V Curves 45 3.6.3 HBM Test 58 3.6.4 Very Fast TLP Test 60 3.7 Comparison 61 3.8 Summary 66 Chapter 4 Realization of Proposed Design with TIA 67 4.1 Introduction 67 4.2 Structure of TIA 67 4.3 Simulation Results of TIA 68 4.3.1 TIA w/o Protection 68 4.3.2 TIA with Traditional π-Diode 70 4.3.3 TIA with Proposed π-SDSCR 71 4.3.4 TIA with Proposed π-RTSCR 73 4.4 Measurement Results of TIA 74 4.4.1 High-frequency Performance 75 4.4.2 TLP I-V Curves 78 4.4.3 HBM Test 79 4.4.4 Very Fast TLP Test 84 4.5 Comparison and Discussion 85 4.6 Summary 90 Chapter 5 Conclusion and Future Work 91 5.1 Conclusion 91 5.2 Future Work 92 Reference 95

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