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博碩士論文 etd-0715118-173415 詳細資訊
Title page for etd-0715118-173415
論文名稱
Title
利用WiFi訊號偵測手勢及深度學習辨識研究
Detection and Deep-Learning Recognition of Hand Gestures Using Wi-Fi Signals
系所名稱
Department
畢業學年期
Year, semester
語文別
Language
學位類別
Degree
頁數
Number of pages
90
研究生
Author
指導教授
Advisor
召集委員
Convenor
口試委員
Advisory Committee
口試日期
Date of Exam
2018-08-09
繳交日期
Date of Submission
2018-08-15
關鍵字
Keywords
深度學習、手勢、注入鎖定正交接收機、都卜勒雷達、注入鎖定振盪器、Wi-Fi
hand gesture, deep learning, injection-locked quadrature receiver, Wi-Fi, doppler radar, injection-locked oscillator
統計
Statistics
本論文已被瀏覽 5797 次,被下載 138
The thesis/dissertation has been browsed 5797 times, has been downloaded 138 times.
中文摘要
本篇論文結合注入鎖定與被動式雷達技術,發展一套能偵測手勢的都卜勒雷達。自身無須產生發射訊號,並使用外部的Wi-Fi訊號,作為感測所需之雷達訊號源。因此雷達接收機的電路架構是本篇的重點,其中電路架構主要又分為注入鎖定振盪器與正交解調器。
首先介紹注入鎖定振盪器,本論文使用環形振盪器的架構來實現擁有較高注入鎖定範圍與寬頻調整範圍的振盪器,且採用TSMC 0.18μm的製程來實作電路。至於正交解調器則以混合式元件搭配印刷電路板的技術來實作。之後再將注入鎖定振盪器與正交解調器結合起來,並與先前本實驗室所使用的接收機電路相互比較效能。比較後,可得到本論文的接收機電路其手勢訊號訊雜比優秀於先前接收機電路的結果。
而為了可以辨識手勢並提高其正確率,本篇論文會介紹深度學習的方法,並使用深度學習去訓練手勢訊號的辨識。得到訊號不同的特徵值再經過神經網路的訓練,判斷出手勢種類,接著透過使用不同的神經網路架構而得到更好的辨識正確率。
Abstract
This thesis presents a passive radar which is able to detect hand gesture by Doppler effect. The Wi-Fi signals are utilized as the signal sources in this radar for detecting a moving target. Since this is a passive radar, the architecture of the radar receiver is the main focus of the work. The radar receiver architecture is divided into two parts, an injection-locked oscillator (ILO) and a quadrature demodulator.
Firstly, this thesis introduces the ILO design method. To fulfill the ILO with a high locking range and wide frequency tuning range, a ring oscillator based ILO was used and implemented using TSMC 0.18μm process. Next, the quadrature demodulator is implemented with hybrid components on a printed circuit board. Then this work combine the ILO and the quadrature demodulator to form the radar receiver, and compares the performance with the radar receiver used in the previous work. It is concluded that the presented radar receiver outperforms the previous one.
To recognize the gesture signals collected from the receiver and to raise the accuracy of recognition, this work uses the deep learning algorithm to train the gesture recognition process. The training procedure outputs different characteristic parameters of the signals, which is useful to recognize the gesture using the neural network. Moreover, different neural network structures were used to improve the accuracy of the gesture recognition.
目次 Table of Contents
目錄

論文審定書 i
論文公開授權書 ii
誌謝 iii
摘要 iv
Abstract v
目錄 vi
圖次 viii
表次 xii
第一章 序論 1
1.1 研究背景與動機 1
1.2 都卜勒雷達簡介 4
1.3 章節規劃 7
第二章 具有寬頻調整範圍之CMOS注入鎖定振盪器 8
2.1 晶片電路設計 8
2.1.1 電路架構的考量與選擇 8
2.1.2 電路設計流程 10
2.1.3 電路設計方法 11
2.1.4 Body-biased架構原理 13
2.2 晶片電路模擬與量測 15
2.2.1 模擬與量測儀器設置 15
2.2.2 模擬與量測結果 17
第三章 手勢感測系統正交解調電路 24
3.1 手勢感測雷達架構簡介 24
3.1.1 直接降頻正交接收機 24
3.1.2 手勢感測雷達 25
3.2 解調電路設計與整合 27
3.2.1 架構考量選擇 27
3.2.2 電路元件選擇 29
3.3 規格測試之性能比較 36
3.4 解調電路應用於手勢雷達之比較 39
第四章 深度學習與應用 50
4.1 深度學習介紹 50
4.1.1 歷史背景 50
4.1.2 深度學習簡介 50
4.1.3 神經網路的基本架構 51
4.2 訓練方法 56
4.2.1 收集數據和訓練流程 56
4.2.2 隱藏層架構介紹:CNN 57
4.2.3 隱藏層架構介紹:RNN 57
4.3 訓練結果 59
第五章 結論 65
參考文獻 66
附錄A 振盪器與注入鎖定理論 71
A.1 注入鎖定振盪器原理 71
A.1.1 振盪條件 71
A.1.2 注入鎖定現象 73
參考文獻 77
參考文獻 References
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