系統識別號 | U0002-1507202015483100 |
---|---|
DOI | 10.6846/TKU.2020.00427 |
論文名稱(中文) | 應用於穿戴式電子裝置之熱電能量擷取具超低自我啟動電壓升壓轉換器 |
論文名稱(英文) | Using Thermal Energy Source Boost Converter with Ultra-low Self-starting Voltage for Wearable Electronic Devices |
第三語言論文名稱 | |
校院名稱 | 淡江大學 |
系所名稱(中文) | 電機工程學系碩士班 |
系所名稱(英文) | Department of Electrical and Computer Engineering |
外國學位學校名稱 | |
外國學位學院名稱 | |
外國學位研究所名稱 | |
學年度 | 108 |
學期 | 2 |
出版年 | 109 |
研究生(中文) | 陳治成 |
研究生(英文) | Jhih-Cheng Chen |
學號 | 606450046 |
學位類別 | 碩士 |
語言別 | 繁體中文 |
第二語言別 | |
口試日期 | 2020-06-29 |
論文頁數 | 74頁 |
口試委員 |
指導教授
-
楊維斌
委員 - 羅有龍 委員 - 施鴻源 委員 - 楊維斌 |
關鍵字(中) |
熱電 能量擷取 超低電壓啟動 電荷幫浦 升壓轉換器 |
關鍵字(英) |
Thermoelectric energy harvesting ultra-low voltage start-up charge pump boost converter |
第三語言關鍵字 | |
學科別分類 | |
中文摘要 |
穿戴式裝置自60年代發展至今,一直是人類文明不可忽視的區塊,由於過去受限於技術以及成本,往往都只限於國防、太空產業。直到2010年代,智慧型手機開始普及,許多大型企業紛紛投入穿戴式裝置的產品開發,讓一般名眾也能享受穿戴式裝置帶來的輔助功能以及便利生活。近年來,物聯網與5G行動網路技術的蓬勃發展,再次帶動了穿戴式以及耳戴式裝置研發,並且出現了〝智慧穿戴〞的名詞。受惠於製程技術的進步及聯網速度的提升,各大廠紛紛進行穿戴式裝置的軍備競賽,不斷的在裝置中加入各種功能與感測器。然而更好的運算效能以及更多的智慧功能換來的是更大的能源消耗,裝置續航力備受考驗。在穿戴式裝置的無線以及輕薄的條件限制下,環境能量擷取被廣泛的討論,如何使用環境中的能量,輔助甚至取代裝置中的電池,是現今主流研究方向。被拿出來討論研究的能量非常多種,常見包含振動、熱電、光能和射頻等能量。然而穿戴式裝置的出發點以人為本,不論是針對一般民眾的消費性穿戴式電子產品又或者是醫療用植入人體的穿戴式裝置,最直接能夠獲取的就是人類體溫,因此本論文將對熱電元件的原理背景以及電源管理電路做分析,目標設計一應用於穿戴式裝置的熱電能量升壓轉換器,並使用TSMC 90nm 1P9M CMOS製程做模擬及實現。電路主要分為升壓轉換器、超低壓啟動電路及電壓控制電路。為了能實現超低電壓啟動並進一步穩定轉換輸出電壓,本文也對過去文獻提出的解決方案做分析,並提出可以實現在50mV超低輸入電壓自我啟動。成功啟動升壓轉換器後,由閘極驅動器使用超低壓啟動電路及電壓控制電路產生之控制訊號對升壓轉換進行控制,最終透過三階段調節,可以提供1V的輸出電壓供後方電路使用。 |
英文摘要 |
Since its development in the 1960s, wearable devices have been an indispensable part of human civilization. Due to the limitations of technology and cost in the past, they were often only used in the military and space industries. Until the 2010s that smartphones became popular, and many large enterprises were investing in the development of wearable devices, allowing the general public to enjoy the accessibility and convenience of wearable devices. In recent years, the vigorous development of the Internet of Things and 5G mobile network technologies has once again driven the development of wearable and ear-worn devices, and the term "smart wear" has appeared. Benefiting from the progress of process technology and the improvement of the speed of networking, Developer have been engaged in the arms race of wearable devices, and constantly add a variety of functions and sensors in the device. However, better computing efficiency and more intelligent features in exchange for greater energy consumption, so the device's endurance is tested. Under the constraints of wireless and thin and lightweight conditions of wearable devices, environmental energy harvesting is widely discussed. How to use energy in the environment to aid or even replace batteries in the device is the mainstream research direction of today. There are many kinds of energy, including vibration, thermoelectricity, solar energy and radio frequency. However, the starting point of the wearable device is people-oriented. Whether it is a consumer wearable electronic product for the general public or a medical wearable device implanted in the human body, the most direct acquisition of energy is the human body temperature. Therefore, this paper will analyze the principle background of thermoelectric components and the power management circuit, the target design of a thermoelectric energy boost converter applied to wearable devices, and use the TSMC 90nm 1P9M CMOS process for simulation and implementation. The circuit is mainly divided into boost converter, ultra-low voltage starting circuit and voltage control circuit. In order to achieve ultra-low voltage start-up and further stabilize the conversion of output voltage, this paper also analyzes the solutions proposed in the past literature and proposes that it can achieve self-start-up at an ultra-low input voltage of 50mV. After the boost converter is successfully started, the gate driver uses the control signal generated by the ultra-low voltage start circuit and the voltage control circuit to control the boost conversion. Finally, through the three-stage adjustment, the proposed circuit can provide an output voltage of 1V for the rear circuit. |
第三語言摘要 | |
論文目次 |
目錄 誌謝 I 中文摘要 II ABSTRACT III 目錄 V 圖目錄 X 表目錄 XV 第一章 緒論 1 1.1研究背景 1 1.2研究動機 2 1.3論文架構 2 第二章 熱電能量擷取技術 3 2.1 熱電能量介紹 3 2.2 熱電效應 3 2.2.1塞貝克效應 4 2.2.2帕爾帖效應 5 2.2.3湯姆森效應 6 2.2.4熱點轉換效率與熱電優值關係 7 2.3 熱電獵能系統 8 2.4 熱電元件等效電路模型 9 第三章 電源管理電路概論 10 3.1 電源管理電路分類 10 3.1.1線性穩壓器 10 3.1.2線性穩壓器工作原理 11 3.1.3切換式電容穩壓器 13 3.1.4開關穩壓器 15 3.1.5降壓轉換器 17 3.1.6升壓轉換器 19 3.1.7升降壓轉換器 20 3.1.8電源管理電路比較 21 3.2 電路控制方式 22 3.2.1 脈波寬度調變 22 3.2.2 脈波頻率調變 24 3.3 導通模式 26 3.3.1連續電流模式 26 3.3.2不連續電流模式 27 3.3.3邊界模式 27 3.4開關穩壓器規格 28 3.4.1輸入電壓範圍 28 3.4.2輸出電壓範圍 28 3.4.3輸出電壓漣波 28 3.4.4開關頻率 30 3.4.5線性調節度 30 3.4.6負載調節度 30 3.4.7暫態響應 31 3.4.8轉換效能與損耗 32 3.4.9電磁干擾 34 第四章 超低壓啟動升壓轉換器 35 4.1超低壓啟動升壓轉換器介紹 35 4.1.1使用電池輔助啟動 36 4.1.2使用機械開關做為啟動元件 37 4.1.3使用LC振盪器做為啟動機制 38 4.1.4使用RF作為啟動機制 39 4.1.5使用電荷幫浦與環形振盪器啟動 40 第五章 電路設計 41 5.1系統架構設計 41 5.2升壓轉換器 42 5.3超低電壓自我啟動電路 44 5.3.1堆疊式數位邏輯 45 5.3.2多相位控制電荷幫浦 46 5.3.3超低電壓雙端環形振盪器 49 5.3.4超低電壓時脈產生器 50 5.4電壓調節電路 51 5.4.1零電流偵測器 51 5.4.2比較器 53 5.4.3脈波頻率調變電路 53 5.4.4電壓偵測器 55 5.4.5閘極驅動器 55 第六章 電路模擬與佈局 58 6.1堆疊式反向器及傳統CMOS反向器 58 6.2超低電壓環形振盪器 60 6.3超低電壓雙端環形振盪器 61 6.4多相位控制電荷幫浦 62 6.5超低電壓時脈產生器 62 6.6電壓偵測器 63 6.7全系統模擬結果 64 6.7.1 Pre-layout simulation Result 64 6.7.2 Post-layout simulation Result 67 6.8佈局平面圖 68 6.9預計規格列表 69 6.10效能比較表 69 第七章 量測考量 70 第八章 結論與未來展望 71 參考文獻 72 圖目錄 圖1.1 能量擷取電源管理架構 1 圖2.1 塞貝克效應示意圖 4 圖2.2 帕爾帖效應示意圖 5 圖2.3 半導體熱電元件結構圖 8 圖2.4 熱電晶片透視圖 8 圖2.5 熱電元件戴維寧等效模型 9 圖2.6 熱電元件串接升壓轉換器等效電路 9 圖3.1 線性穩壓器基本架構 11 圖3.2 低壓降線性穩壓器基本架構 11 圖3.3 升壓型切換式電容穩壓器 13 圖3.4 控制時脈 (CLK) 為低準位時的等效電路 14 圖3.5 控制時脈 (CLK) 為高準位時的等效電路 14 圖3.6 開關穩壓器基本架構 15 圖3.7 開關穩壓器基本操作時緒 16 圖3.8 降壓轉換器基本架構 17 圖3.9 功率開關MP導通時等效電路 17 圖3.10 功率開關MP截止時等效電路 18 圖3.11 升壓轉換器基本架構 19 圖3.12 升降壓轉換器基本架構 20 圖3.13 脈波寬度調變電路 22 圖3.14 脈波寬度調變電路波型 23 圖3.15 脈波頻率調變電路 25 圖3.16 脈波頻率調變電路波型 25 圖3.17 降壓轉換器之連續導通模式狀態圖 26 圖3.18 降壓轉換器不連續導通狀態圖 27 圖3.19 輸出電壓漣波 29 圖3.20 輸出電壓負載變化暫態響應圖 32 圖3.21 效能轉換表示圖 33 圖4.1 利用電池輔助低壓啟動升壓轉換器系統架構 36 圖4.2 機械輔助啟動電路來啟動從熱電元件提取能量 37 圖4.3 使用LC振盪器之低壓啟動電路 38 圖4.4 使用RF低壓啟動機制 39 圖4.5使用電荷幫浦與環形振盪器之啟動電路架構 40 圖5.1 應用於穿戴式電子裝置熱電能量擷取之具超低自我啟動電壓升壓轉換器使用多相位電荷幫浦和超低壓差動環形振盪器 42 圖5.2 升壓轉換器架構 43 圖5.3 升壓轉換器操作情形 44 圖5.4 超低電壓自我啟動電路架構圖 44 圖5.5 (a)堆疊式反向器架構 (b)堆疊式反向器圖示 45 圖5.6 堆疊式反及閘 46 圖5.7 狄克森充電幫浦 47 圖5.8 交叉耦合電荷幫浦 47 圖5.9 充電幫浦單元損耗示意圖 48 圖5.10 多相位控制電荷幫浦 48 圖5.11 雙端延遲單元 49 圖5.12 超低電壓雙端環型振盪器電路 49 圖5.13 時脈產生器 50 圖5.14 時脈產生器區塊 50 圖5.15 電壓調節電路 51 圖5.16 零電流偵測器 52 圖5.17 零電流偵測時序圖 52 圖5.18 比較器 53 圖5.19 脈波頻率調變電路 54 圖5.20 脈波頻率調變時序圖 54 圖5.21 電壓偵測器 55 圖5.22 閘極驅動器架構 55 圖5.23 啟動階段 56 圖5.24 過渡階段 56 圖5.25 調節穩壓階段 57 圖6.1 兩種反向器之NMOS的RDS變化 58 圖6.2 兩種反向器之PMOS的RDS變化 59 圖6.3 環形振盪器輸出波型圖 60 圖6.4 超低電壓雙端環形振盪器模擬結果 61 圖6.5 多相位控制電荷幫浦與交叉耦合電荷幫浦輸出結果 62 圖6.6 超低電壓時脈產生器輸出結果 63 圖6.7 電壓偵測器VIN對VOUT模擬圖 63 圖6.8 全系統在TT corner,27˚C模擬結果 (輸出電壓、電感電流、控制訊號) 64 圖6.9 全系統在TT corner, 27˚C模擬結果(電流偵測、PFM訊號) 64 圖6.10 全系統在SS corner, 0˚C模擬結果 (輸出電壓、電感電流、控制訊號) 65 圖6.11 全系統在SS corner, 0˚C模擬結果(電流偵測、PFM訊號) 65 圖6.12 全系統在FF corner, 75˚C模擬結果 (輸出電壓、電感電流、控制訊號) 66 圖6.13 全系統在FF corner, 75˚C模擬結果(電流偵測、PFM訊號) 66 圖6.14 全系統在TT corner,27˚C模擬結果 (輸出電壓、電感電流、控制訊號、PFM訊號) 67 圖6.15 電路佈局圖 68 圖7.1 量測環境示意圖 70 表目錄 表3.1電源管理電路之特性比較 21 表6.1 超低電壓環境下電晶體開關時等效RDS大小 59 表6.2 三種環型振盪器架構輸出規格比較 61 表6.3 預計規格列表 69 表6.4 效能比較表 69 |
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