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研究生: 周柏瑄
Chou, Po-Hsuan
論文名稱: 非持久性載波之無電池背向散射通訊系統
Battery-Free Backscatter Communication Systems with Non-Persistent Carriers
指導教授: 王超
Wang, Chao
蒂莫·沃伊特
Voigt, Thiemo
口試委員: 王科植
Wang, Ko-Chih
克里斯蒂安·羅納
Rohner, Christian
蒂莫·沃伊特
Voigt, Thiemo
王超
Wang, Chao
口試日期: 2023/06/16
學位類別: 碩士
Master
系所名稱: 資訊工程學系
Department of Computer Science and Information Engineering
論文出版年: 2023
畢業學年度: 111
語文別: 英文
論文頁數: 50
中文關鍵詞: 無電池物聯網設備背向散射通訊間歇運算
英文關鍵詞: Battery-Free IoT Devices, Backscatter Communication, Intermittent Computing
研究方法: 實驗設計法
DOI URL: http://doi.org/10.6345/NTNU202301505
論文種類: 學術論文
相關次數: 點閱:71下載:3
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  • 近年來,物聯網(IoT)設備的數量顯著增加,這造成了電池更換時間及成本的挑戰。無電池(Battery-Free)物聯網設備使用電容和能量擷取器(Energy Harvester)來收集環境能量,例如太陽能或射頻(Radio Frequency)。一般來說,這些物聯網設備的日常任務,尤其是資料傳輸,通常會消耗大量能源。這可能會導致無電池系統耗盡電容中的能量。背向散射通訊(Backscatter Communication)是一種新穎的無線通訊方法,其使用環境中的載波訊號 (Carrier Signal)來實現物聯網設備之間的低功耗通訊。但背向散射通訊下的傳輸仍然存在一些限制。一個明顯的限制是背向散射通訊的傳輸僅能在載波訊號可用時才能工作。在設備由能量擷取器供電的無電池背向散射通訊系統中,由於環境能量不穩定,所有設備都可能發生斷電。最壞的情況下,由於載波訊號不活動,加上環境能量不可用,設備最終將耗盡能量,資料將面臨丟失。本論文透過使用另一篇論文中提出的射頻檢測器(RF Detector)來演示硬體設計的不同策略,這種電路設計可以幫助背向散射標籤識別載波是否可用。本論文考量載波可用性的到達率和環境能量擷取效率等不同情況下,提出解決策略 — TagDN,其旨在減輕背向散射標籤能量耗盡時發生的資料丟失問題。本論文同時分析了不同設置下所接收的封包數量和接收產率(Data Yield)。實驗結果表明,如果沒有射頻檢測器以及非揮發性記憶體(Non-Volatile Memory)等額外硬體支持,無論是封包接收數量還是接收產率,表現都是最差的。總結來說,若背向散射標籤包含額外的硬體支援,則封包接收數量和接收產率可以有顯著地提昇。

    In recent years, there has been a significant increase in the number of Internet-of-Things
    (IoT) devices, which has led to challenges related to the time and cost associated with
    battery replacement. Battery-free IoT devices use capacitors and energy harvesters to
    capture the ambient energy such as solar power and radio frequency. In general, some
    routine tasks of those devices, especially data transmission, often cost high energy con-
    sumption. This might lead to a situation where the battery-free system runs out its
    energy in the capacitor. Backscatter communication, a novel wireless communication
    method, uses the ambient carrier signal to enable low-power communication between
    IoT devices. But the transmission under backscatter communication still has some limi-
    tations. One significant limitation is that the transmission of backscatter communication
    can only work while the carrier signal is available. In a battery-free backscatter commu-
    nication system where devices are powered by energy harvesters, all devices may suffer
    power failure since the ambient energy is unreliable. In the worst case, the data will lose
    and the device will run out of energy because the carrier signal is inactive and ambi-
    ent energy is unavailable. This thesis demonstrates the different strategies in usage of
    hardware design by using as RF detector proposed in another paper. This circuit design
    can help backscatter tag to identify whether the carrier is active or not. Experiment
    result shows the different arrival rate of carrier availability and harvesting environment.
    The proposed strategy TagDN aims to mitigate the issue of data loss that occurs when the backscatter tag runs out of energy. This thesis also analyzed the total number of
    received packets and the data yield under these different setups of our experiments. The
    experiment results confirm that if there is no additional hardware support such as RF de-
    tector and non-volatile memory, both the number of received packets and the data yield
    are in the worst performance. In summary, a backscatter tag includes both additional
    hardwares support, the number of received packets and the data yield can be improved
    significantly.

    1 Introduction 1 1.1 Background 1 1.2 Problem Statement 2 1.3 Thesis Contribution and Organization 4 2 Related Work 5 2.1 Backscatter Communication 5 2.2 Backscatter Communication with Commodity Protocol 6 3 System Model 8 3.1 Overview of Backscatter Communication 8 3.2 Battery-Free Backscatter Communication IoT Devices 10 4 Implementation 12 4.1 The Architecture of Backscatter Tag Node 13 4.2 Carrier Signal Detector 14 4.3 Backscatter Tag 15 4.4 Carrier Generator and Receive Node 16 4.5 Methods 17 4.5.1 Baseline Approach 17 4.5.2 TagCD 19 4.5.3 TagDN 20 4.6 Threshold Calculation 22 4.7 Battery-Free Power Simulations 23 5 Empirical Validation 26 5.1 Experiment Setup 26 5.2 Carrier Simulation Definition 27 5.3 Experiment I 31 5.3.1 Receive Packets Analysis 32 5.3.2 Data Yield Analysis 37 5.4 Experiment II 40 5.4.1 Experiment Result 40 5.4.2 Summary 41 5.5 Experiment III 42 5.5.1 Experiment Result 43 5.6 Summary of Empirical Validation 43 6 Conclusion 45 6.1 Conclusion 45 6.2 Future Work 46 References 47 Vita 50

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