跳到主要內容

簡易檢索 / 詳目顯示

回結果列表
研究生: 林再文
Zai-Wun Lin
論文名稱: 先進電離層探測儀
Advanced Ionospheric Probe
指導教授: 趙吉光
Chi-Kuang Chao
口試委員:
學位類別: 博士
Doctor
系所名稱: 地球科學學院 - 太空科學研究所
Graduate Institute of Space Science
論文出版年: 2016
畢業學年度: 105
語文別: 中文
論文頁數: 184
中文關鍵詞: 先進電離層探測儀福爾摩沙衛星五號電漿量測阻滯電位分析儀離子流向儀探空九號火箭
外文關鍵詞: Advanced Ionospheric Probe, FORMOSAT-5, plasma diagnostics, retarding potential analyzer, ion drift meter, sounding rocket 9
相關次數: 點閱:17下載:0
分享至:
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報

    • 先進電離層探測儀是以單一探測器來實現複合式量測的電漿探測儀器,能透過分時的方式扮演平面電漿探針、阻滯電位分析儀、離子流向儀、與離子捕獲儀各項功能。將搭載於福爾摩沙衛星五號上,實地量測電離層的電漿成份、密度、溫度、運動速度等物理量。先進電離層探測儀具備體積小、重量輕等特性,其儀器角色可以透過衛星指令更改,具備高度的量測彈性,為完全由國人自製的衛星級儀器。先進電離層探測儀搭載了同級電漿量測酬載中最高的每秒 8,192 次的取樣率,可量測電離層的細微結構;探測器所使用的純金電鑄篩網,理論上可維持較好的等電位面結構,從實驗結果中也顯示具有較低的類磁滯現象,可使量測結果更為精確;探測器所採用的圓形開口相較於以往慣用的方型開口不同,其理論模型已經發展完成,並在實驗中證明可以應用於電漿流向的推算。先進電離層探測儀已經完成所有的功能測試與環境測試,並完成了探空九號火箭的飛行測試,其效能符合預期,將可於軌道上執行任務。

    Advanced Ionospheric Probe (AIP) is an all-in-one plasma sensor that uses single instrument to perform multiple sensor functions---includes the Planar Langmuir Probe, the Retarding Potential Analyzer, the Ion Drift Meter, and the Ion Trap---in a time sharing mechanism. AIP is a science payload for FORMOSAT-5 satellite to perform in situ measurement on the ionospheric plasma compositions, concentrations, temperatures, and velocities. AIP is fully made in Taiwan with features such as light weight, compact size, and software-programmable in sensor functions to archive high flexibilities in science operations. AIP has the highest sampling rate 8,192 samples per second in similar plasma payloads to measurement the detail plasma structures in ionosphere. The electro-forming golden grids are used to maintain the smoothness of the potential surface and improve the measurement accuracy. It shows that the quasi-hysteresis effect is reduced from an experiment in laboratory. Meanwhile, AIP uses circular aperture opening instead of the traditional square opening to measure the arrival angle of incoming plasma flow. A theory is developed and identified by experiments. AIP has passed all functional and environmental tests, and completed a pre-flight test on Taiwan's sounding rocket 9 mission. The instrument performance is as expected and is ready for launch in the future.

    中文摘要 i 英文摘要 iii 誌謝 v 目錄 vii 圖目錄 xi 表目錄 xvii 1 介紹 1 1.1 電離層 1 1.2 福爾摩沙衛星五號 2 1.3 先進電離層探測儀 3 1.4 科學任務 5 1.4.1 赤道地區電漿不規則體 5 1.4.2 背景電離層 6 1.4.3 磁暴期間之電離層擾動 7 1.4.4 電離層地震前兆研究 7 1.5 章節說明 8 2 量測原理 9 2.1 平面電漿探針 2.2 阻滯電位分析儀 2.3 離子捕獲儀 13 2.4 離子流向儀 13 2.4.1 基本原理 13 2.4.2 備援原理 16 2.4.3 反矩陣 17 3 硬體架構 19 3.1 探測器 20 3.1.1 AMM 21 3.1.2 CBS 24 3.1.3 SPI 27 3.1.4 電流計設計 28 3.1.5 掃描電壓設計 30 3.2 科學酬載電子系統 30 3.2.1 電氣介面 31 3.2.2 通訊架構 32 3.2.3 電源架構與電源模組 33 3.2.4 過流保護電路 34 3.2.5 備援設計 35 3.2.6 掃描電壓預置區塊 35 3.3 座標系統 37 3.4 硬體規格 37 4 軟體架構 41 4.1 操作模式與設定 42 4.1.1 操作次階模式 42 4.1.2 操作限制 44 4.2 通訊介面 45 4.2.1 指令與遙傳介面 45 4.2.2 科學資料介面 46 4.2.2.1 科學資料封包 47 4.2.2.2 封包傳輸率 48 4.2.2.3 封包內容排列時序 49 4.2.2.4 科學資料與次階模式 51 4.2.2.5 測試模式 53 4.3 科學操作 55 4.3.1 正常模式 56 4.3.2 快速模式 57 4.3.3 高速模式 57 4.3.4 備援操作 58 4.4 量測規格 59 5 功能與環境測試 61 5.1 功率量測 61 5.2 電路保護測試 63 5.3 電流注入測試 66 5.4 熱真空測試 68 5.5 振動測試 76 5.5.1 正弦振動測試 77 5.5.2 隨機振動測試 78 5.5.3 衝擊測試 80 5.5.4 測試結果 81 5.6 電磁相容測試 83 5.7 燒機測試 83 6 電漿注入與飛行測試 87 6.1 電漿注入測試 89 6.1.1 實驗結果預覽 91 6.1.2 在快速與高速模式下的量測 93 6.1.3 IDM 方形開口與圓形開口的比較 94 6.1.4 IDM 的備援應用 97 6.2 探空九號火箭飛行測試 99 7 結論 107 參考文獻 109 A 相關資料 115 A.1 數學推導 115 A.1.1 離子流量方程式 115 A.1.2 圓上任兩割線所形成的面積關係 117 A.2 SPEU 接頭接腳定義 123 A.3 指令與遙傳介面 128 A.3.1 字元與封包規範 128 A.3.2 指令封包 128 A.3.3 衛星輔助資料封包 129 A.3.4 酬載狀態資訊封包 131 A.4 科學資料介面 134 A.4.1 字元與封包規範 134 A.4.2 科學資料封包主要標題格式 135 B AIP Sensor Control Handout 137 B.1 Sensor DIO and its related controls 137 B.2 SPI configurations for ADC, DAC and TMP 139 B.2.1 Hardware configuration of ADC 141 B.2.2 Hardware configuration of DAC 142 B.2.3 Hardware configuration of TMP 144 B.2.4 Sleep mode 144 B.2.5 Sampling requirement 145 B.3 Sweeping voltage blocks 152 B.4 More on SPEU-side controlled signals 154 B.5 SPI control considerations 155 B.5.1 Time delay 155 B.5.2 Demultiplexer switching glitch 158 B.6 CBS boards IO 158

    Abe, T., and K. ichiro Oyama, Langmuir probe, in An Introduction to Space Instru- mentation, edited by K. Oyama and C. Z. Cheng, pp. 63–75, Terrapub, Tokyo, doi: 10.5047/aisi.010, 2013.
    Bailey, G. J., M. H. Denton, R. A. Heelis, and S. Venkatraman, A modelling study of the latitudinal variations in the nighttime plasma temperatures of the equatorial topside ionosphere during northern winter at solar maximum, Annales Geophysicae, European Geosciences Union, 18(11), 1435–1446, 2000.
    Berthelier, J., M. Godefroy, F. Leblanc, E. Seran, D. Peschard, P. Gilbert, and J. Artru, IAP, the thermal plasma analyzer on DEMETER, Planetary and Space Science, 54(5), 487 – 501, doi:http://dx.doi.org/10.1016/j.pss.2005.10.018, first Results of the DEMETER Micro-Satellite, 2006.
    Bevington, P. R., Data Reduction and Error Analysis for the Physical Sciences, McGraw- Hill Inc., 2002.
    Bilitza, D., International reference ionosphere 2000, Radio Science, 36(2), 261–275, 2001. Chao, C. K., FORMOSAT-5 Advanced Ionospheric Probe Science Mission Definition
    Document, Tech. rep., Institute of Space Science, National Central University, 2012. Chao, C. K., FORMOSAT-5 Advanced Ionospheric Probe Interface Control Document,
    Tech. rep., Institute of Space Science, National Central University, 2013.
    Chao, C. K., and S.-Y. Su, Charged particle motion inside the retarding potential analyzer,
    Physics of Plasmas, 7(1), 101–107, doi:http://dx.doi.org/10.1063/1.873817, 2000.
    Chao, C. K., S.-Y. Su, and H. Yeh, Grid effects on the derived ion temperature and ram velocity from the simulated results of the retarding potential analyzer data, Advances in Space Research, 32(11), 2361 – 2366, doi:http://dx.doi.org/10.1016/S0273-1177(03) 90566-7, 2003a.
    Chao, C. K., S.-Y. Su, and H. Yeh, Calibration, characterization of satellite sensors, phys- ical parameters derived from satellite data grid effects on the derived ion tempera- ture and ram velocity from the simulated results of the retarding potential analyzer data, Advances in Space Research, 32(11), 2361 – 2366, doi:http://dx.doi.org/10.1016/ S0273-1177(03)90566-7, 2003b.
    Chao, C. K., S.-Y. Su, and H. C. Yeh, Ion temperature crests and troughs in the morning sector of the low-latitude and midlatitude topside ionosphere, Journal of Geophysical Research: Space Physics, 109(A11), doi:10.1029/2003JA010360, a11303, 2004.
    Chao, C. K., S.-Y. Su, and H. Yeh, Ion temperature variation observed by ROCSAT-1 satellite in the afternoon sector and its comparison with IRI-2001 model, Advances in Space Research, 37(5), 879 – 884, doi:http://dx.doi.org/10.1016/j.asr.2005.06.071, advances in Specifying Plasma Temperatures and Ion Composition in the Ionosphere, 2006.
    Chao, C. K., S.-Y. Su, J. D. Huba, and K.-I. Oyama, Modeling the presunrise plasma heat- ing in the low- to midlatitude topside ionospheres, Journal of Geophysical Research: Space Physics, 115(A9), doi:10.1029/2009JA014923, a09304, 2010.
    Chao, C. K., Y. H. Chu, C. L. Su, and S. Minami, In-Situ Measurement of Ionospheric E- Region Plasma Irregularities over Taiwan, Terr. Atmos. Ocean., 23(3), 333–342, 2012.
    Chao, C. K., Z. W. Lin, Y. C. Mao, and Y. S. Chang, System architecture of Advanced Ionospheric Probe onboard FORMOSAT-5 satellite, 2016.
    Chen, K. Y., H. C. Yeh, S. Y. Su, C. H. Liu, and N. E. Huang, Anatomy of plasma structures in an equatorial spread F event, Geophysical Research Letters, 28(16), 3107–3110, doi: 10.1029/2000GL012805, 2001.
    Corliss, W. R., NASA Sounding Rockets, 1958-1968, A Historical Summary, The NASA Historical Report Series, 1971.
    Davies, K., Ionospheric Radio, Peter Peregrinus Ltd., London, 1990.
    Greenspan, M. E., C. E. Rasmussen, W. J. Burke, and M. A. Abdu, Equatorial density depletions observed at 840 km during the great magnetic storm of March 1989, Jour- nal of Geophysical Research: Space Physics, 96(A8), 13,931–13,942, doi:10.1029/ 91JA01264, 1991.
    Haerendel, G., Theory of Equatorial Spread F, 1973.
    Hanson, W. B., A. F. Nagy, and R. J. Moffett, Ogo 6 measurements of supercooled plasma in the equatorial exosphere, Journal of Geophysical Research, 78(4), 751–756, doi: 10.1029/JA078i004p00751, 1973.
    Heelis, R. A., and W. B. Hanson, Measurements of Thermal Ion Drift Velocity and Tem- perature Using Planar Sensors, American Geophysical Union, 102, 61, doi:10.1029/ GM102p0061, 1998.
    Hsu, P. L., FORMOSAT-5 Advanced Ionospheric Probe Circuit Protection Test Procdure, Tech. rep., Institute of Space Science, National Central University, 2013a.
    Hsu, Y. T., FORMOSAT-5 Advanced Ionospheric Probe Test Report, Tech. rep., Institute of Space Science, National Central University, 2013b.
    Hsu, Y. T., FORMOSAT-5 Advanced Ionospheric Probe Conducted EMC Test Procedure, Tech. rep., Institute of Space Science, National Central University, 2013c.
    Kelly, M. C., The Earth’s Ionosphere: Plasma Physics and Electrodynamics, Academic Press, Inc., 1989.
    Lin, C. S., H. C. Yeh, and S.-Y. Su, ROCSAT-1 satellite observations of magnetic anomaly density structures during the great magnetic storm of July 15-16, 2000, Terr. Atmos. Ocean., 2000.
    Lin, Z. W., FORMOSAT-5 Advanced Ionospheric Probe Power Measurement Test Proc- dure, Tech. rep., Institute of Space Science, National Central University, 2013a.
    Lin, Z. W., FORMOSAT-5 Advanced Ionospheric Probe Current Injection Test Procdure, Tech. rep., Institute of Space Science, National Central University, 2013b.
    Lin, Z. W., FORMOSAT-5 Advanced Ionospheric Probe Plasma Injection Test Procdure, Tech. rep., Institute of Space Science, National Central University, 2013c.
    Lin, Z. W., FORMOSAT-5 Advanced Ionospheric Probe System Operation Handbook, Tech. rep., Institute of Space Science, National Central University, 2014.
    Lin, Z.-W., C.-K. Chao, J.-Y. Liu, C.-M. Huang, Y.-H. Chu, C.-L. Su, Y.-C. Mao, and Y.- S. Chang, Scientific Mission of Advanced Ionospheric Probe Onboard FORMOSAT-5 Satellite, Terr. Atmos. Ocean., 2016.
    Liu, J. Y., and C. K. Chao, An observing system simulation experiment for FORMOSAT-5/ AIP detecting seismo-ionospheric precursors, 2016.
    Liu, Y. H., C. K. Chao, S.-Y. Su, and C. H. Liu, Study of a coincident observation between the ROCSAT-1 density irregularity and Ascension Island scintillation, Radio Science, 47(5), doi:10.1029/2011RS004908, rS5001, 2012.
    McClure, J. P., S. Singh, D. K. Bamgboye, F. S. Johnson, and H. Kil, Occurrence of equa- torial F region irregularities: Evidence for tropospheric seeding, Journal of Geophysical Research: Space Physics, 103(A12), 29,119–29,135, doi:10.1029/98JA02749, 1998.
    Ossakow, S. L., Spread-F theories—a review, Journal of Atmospheric and Terrestrial Physics, 43(5-6), 437–452, doi:10.1016/0021-9169(81)90107-0, 1981.
    Oyama, K.-I., Y. Kakinami, J.-Y. Liu, M. Kamogawa, and T. Kodama, Reduction of elec- tron temperature in low-latitude ionosphere at 600 km before and after large earth- quakes, Journal of Geophysical Research: Space Physics, 113(A11), doi:10.1029/ 2008JA013367, a11317, 2008.
    Ratcliffe, J. A., Introduction to the Ionospheric and Magnetosphere, Cambridge Univer- sity Press, London, 1972.
    Rich, F. J., Users guide for the topside ionospheric plasma monitor (ssies, ssies-2 and ssies-3) on spacecraft of the defense meteorological satellite program, Environmental Research Papers, Vol. I: Technical Description(1151), 1994.
    Rishbeth, H., and O. Garriott, Introduction to Ionospheric Physics, International geo- physics series, Academic Press, 1969.
    Schuttauf, A., S. Rakers, and C. Daniel, Radiation Test of 8 Bit Microcontrollers AT- mega128 amp; AT90CAN128, pp. 4–4, doi:10.1109/REDW.2010.5619504, 2010.
    Su, S.-Y., H. C. Yeh, and R. A. Heelis, ROCSAT 1 ionospheric plasma and electrody- namics instrument observations of equatorial spread F: An early transitional scale re- sult, Journal of Geophysical Research: Space Physics, 106(A12), 29,153–29,159, doi: 10.1029/2001JA900109, 2001.
    Su, S.-Y., H. C. Yeh, C. K. Chao, and R. A. Heelis, Observation of a large density dropout across the magnetic field at 600 km altitude during the 6–7 April 2000 magnetic storm, Journal of Geophysical Research: Space Physics, 107(A11), SIA 18–1–SIA 18–9, doi: 10.1029/2001JA007552, 1404, 2002.
    Su, S.-Y., C. H. Liu, H. H. Ho, and C. K. Chao, Distribution characteristics of topside ionospheric density irregularities: Equatorial versus midlatitude regions, Journal of Geophysical Research: Space Physics, 111(A6), doi:10.1029/2005JA011330, a06305, 2006.
    Venkatraman, S., and R. Heelis, Longitudinal and seasonal variations in nighttime plasma temperatures in the equatorial topside ionosphere during solar maximum, Jour- nal of Geophysical Research: Space Physics, 104(A2), 2603–2611, doi:10.1029/ 1998JA900109, 1999.
    Whipple, J., E. C., The equilibrium electric potential of a body in the upper atmosphere and in interplanetary space, Ph.D. thesis, 1965.
    Yeh, H. C., S. Y. Su, Y. C. Yeh, J. M. Wu, R. A. Heelis, and B. J. Holt, Scientific mission of the IPEI payload onboard ROCSAT-1, Terr. Atmos. Ocean., 1999.
    Yeh, K. C., and C. H. Liu, Theory of Ionospheric Waves, Academic Press, New York, 1973.
    Zuccaro, D. R., and B. J. Holt, A technique for establishing a reference potential on satellites in planetary ionospheres, Journal of Geophysical Research: Space Physics, 87(A10), 8327–8329, doi:10.1029/JA087iA10p08327, 1982.
    周彥含, 先進電離層探測儀地面電子測試設備, Master's thesis, 國立中央大學, 2013.
    曹智涵, 探空十號火箭的姿態重建與分析, Master's thesis, 國立中央大學, 2015.
    朱宴達, 微衛星離子探測系統, Master's thesis, 國立中央大學, 2011.
    林再文, 太空離子探測系統, Master's thesis, 國立中央大學, 2010.
    洪晟銘, 太空電漿模擬艙自動化監控系統, Master's thesis, 國立中央大學, 2016.
    胡紹賢, 太空電漿探針系統, Master's thesis, 國立中央大學, 2008.
    茅雅䪧, 先進電離層探測儀之機構設計與分析, Master's thesis, 國立中央大學, 2013.
    陳冠文, 先進電離層探測儀離子流向推導與校正, Master's thesis, 國立中央大學, 2013.

    QR CODE
    :::