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題名 以四旋翼UAS酬載熱感測器製作數值表面溫度模型供地溫研究
Generation of digital surface temperature model from images collected by thermal sensor on quadcopter UAS for geothermal study
作者 謝耀震
Hsieh, Yao-Chen
貢獻者 邱式鴻
Chio, Shih-Hong
謝耀震
Hsieh, Yao-Chen
關鍵詞 無人機
熱像
定位定向
光束法空三平差
熱像儀率定
三焦張量
Unmanned aircraft system
Thermal images
Positioning and orientation
Bundle adjustment aerial triangulation
Thermal camera calibration
Trifocal tensor
日期 2017
上傳時間 1-Mar-2017 17:24:13 (UTC+8)
摘要 熱像儀,能感測可見光感測器無法取得的訊息,因此若能透過熱像儀器進行環境偵測,便能得到一般可見光感測器無法獲取的資料。本研究擬以四旋翼UAS酬載熱像儀得到局部區域高解析度之地面熱資訊以便作為地溫研究之背景資料使用。而一般地溫研究區,不易佈設控制點,因此本研究除於無人機上酬載熱像儀之外,並將搭載Trimble BD970 GNSS OEM接收模組,嘗試以少量地面控制點、以及GNSS動態後處理的方式取得取像時對應的GNSS觀測量輔助熱像定位定向。本研究中針對國立政治大學旁的指南溪實驗區與陽明山國家公園的小油坑實驗區,使用AI-RIDER YJ-1000-HC四旋翼UAS分別酬載熱像儀FLIR Tau 640和巨哥XM6,並且同時搭載Trimble BD970 GNSS OEM接收模組、以及GNSS動態後處理的方式取得取像時對應的GNSS觀測量搭配少量地面控制點輔助熱像定位定向,過程中透過三焦張量剔除自動匹配之誤匹配連結點。實驗結果顯示,兩實驗區所產製之DSM於不易變動區域精度經現有資料檢核均在±1m,而指南溪實驗區產製出地面解析度11公分的數值表面模型(Digital Surface Model, DSM)與正射熱像,且正射熱像平面精度達為47公分;小油坑實驗區產製出地面解析度14公分之DSM與正射熱像,正射熱像平面精度則為67公分,雖然DSM和正射熱像精度無法符合一般常規的測量規範,但成果仍然可以證明熱像直接產製DSM以及正射熱像之可行性,兩實驗區最後皆生成數值溫度表面模型(Digital Surface Temparature Model, DSTM),顯示本研究所提方法之可行性,所生成之成果可供後續地溫研究使用。
Thermal infrared images show the temperature change of sensed scenes. Therefore, thermal infrared camera can sense some important information that optical digital cameras cannot do for the environment monitoring. In this study, the Quadcopter UAS for thermal image collection applied to geothermal study will be developed. FIIR Tau 640 and Magnity Eletric XM6 thermal infrared sensor will be used in this thermal image collection system separately two test areas, Zhinan River nearby NCCU and Xiaoyoukeng, in the Yangmingshan National Park. Additionally, Trimble BD970 GNSS OEM board will be carried on the Quadcopter UAS to collect dual-frequency GNSS observations for determining the flying trajectory by Post-processed kinematic (PPK) technique to support the positioning and orientating of collected thermal images, and the trifocal tensor will be used to delete wrong matching tie images points. From the tests, the differences between produced DSM and existing DSM data are ± 1 m on uneasy change ground surface in two test areas. The resolution of produced DSM and thermal orthoimages are about 11 cm in Zhinan River, and 14cm in Xiaoyoukeng area. The accuracy of thermal orthoimages is 47cm in Zhinan River and 67cm in Xiaoyoukeng area. The accuracy of thermal orthoimages may not comply with a normal surveying standard, but it proves the possibility of DSM and orthorectifed thermal images generated from thermal images directly. Digital Surface Temparature Model (DSTM) produced in both tests can be used for volcanic geothermal monitoring in the future.
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描述 碩士
國立政治大學
地政學系
103257032
資料來源 http://thesis.lib.nccu.edu.tw/record/#G0103257032
資料類型 thesis
dc.contributor.advisor 邱式鴻zh_TW
dc.contributor.advisor Chio, Shih-Hongen_US
dc.contributor.author (Authors) 謝耀震zh_TW
dc.contributor.author (Authors) Hsieh, Yao-Chenen_US
dc.creator (作者) 謝耀震zh_TW
dc.creator (作者) Hsieh, Yao-Chenen_US
dc.date (日期) 2017en_US
dc.date.accessioned 1-Mar-2017 17:24:13 (UTC+8)-
dc.date.available 1-Mar-2017 17:24:13 (UTC+8)-
dc.date.issued (上傳時間) 1-Mar-2017 17:24:13 (UTC+8)-
dc.identifier (Other Identifiers) G0103257032en_US
dc.identifier.uri (URI) http://nccur.lib.nccu.edu.tw/handle/140.119/106931-
dc.description (描述) 碩士zh_TW
dc.description (描述) 國立政治大學zh_TW
dc.description (描述) 地政學系zh_TW
dc.description (描述) 103257032zh_TW
dc.description.abstract (摘要) 熱像儀,能感測可見光感測器無法取得的訊息,因此若能透過熱像儀器進行環境偵測,便能得到一般可見光感測器無法獲取的資料。本研究擬以四旋翼UAS酬載熱像儀得到局部區域高解析度之地面熱資訊以便作為地溫研究之背景資料使用。而一般地溫研究區,不易佈設控制點,因此本研究除於無人機上酬載熱像儀之外,並將搭載Trimble BD970 GNSS OEM接收模組,嘗試以少量地面控制點、以及GNSS動態後處理的方式取得取像時對應的GNSS觀測量輔助熱像定位定向。本研究中針對國立政治大學旁的指南溪實驗區與陽明山國家公園的小油坑實驗區,使用AI-RIDER YJ-1000-HC四旋翼UAS分別酬載熱像儀FLIR Tau 640和巨哥XM6,並且同時搭載Trimble BD970 GNSS OEM接收模組、以及GNSS動態後處理的方式取得取像時對應的GNSS觀測量搭配少量地面控制點輔助熱像定位定向,過程中透過三焦張量剔除自動匹配之誤匹配連結點。實驗結果顯示,兩實驗區所產製之DSM於不易變動區域精度經現有資料檢核均在±1m,而指南溪實驗區產製出地面解析度11公分的數值表面模型(Digital Surface Model, DSM)與正射熱像,且正射熱像平面精度達為47公分;小油坑實驗區產製出地面解析度14公分之DSM與正射熱像,正射熱像平面精度則為67公分,雖然DSM和正射熱像精度無法符合一般常規的測量規範,但成果仍然可以證明熱像直接產製DSM以及正射熱像之可行性,兩實驗區最後皆生成數值溫度表面模型(Digital Surface Temparature Model, DSTM),顯示本研究所提方法之可行性,所生成之成果可供後續地溫研究使用。zh_TW
dc.description.abstract (摘要) Thermal infrared images show the temperature change of sensed scenes. Therefore, thermal infrared camera can sense some important information that optical digital cameras cannot do for the environment monitoring. In this study, the Quadcopter UAS for thermal image collection applied to geothermal study will be developed. FIIR Tau 640 and Magnity Eletric XM6 thermal infrared sensor will be used in this thermal image collection system separately two test areas, Zhinan River nearby NCCU and Xiaoyoukeng, in the Yangmingshan National Park. Additionally, Trimble BD970 GNSS OEM board will be carried on the Quadcopter UAS to collect dual-frequency GNSS observations for determining the flying trajectory by Post-processed kinematic (PPK) technique to support the positioning and orientating of collected thermal images, and the trifocal tensor will be used to delete wrong matching tie images points. From the tests, the differences between produced DSM and existing DSM data are ± 1 m on uneasy change ground surface in two test areas. The resolution of produced DSM and thermal orthoimages are about 11 cm in Zhinan River, and 14cm in Xiaoyoukeng area. The accuracy of thermal orthoimages is 47cm in Zhinan River and 67cm in Xiaoyoukeng area. The accuracy of thermal orthoimages may not comply with a normal surveying standard, but it proves the possibility of DSM and orthorectifed thermal images generated from thermal images directly. Digital Surface Temparature Model (DSTM) produced in both tests can be used for volcanic geothermal monitoring in the future.en_US
dc.description.tableofcontents 第一章 緒論 1
第一節 研究背景 1
第二節 研究動機與目的 3
第三節 遭遇的問題與解決方法 5
第四節 研究流程與架構 7
第二章 文獻回顧 11
第一節 熱像儀率定 11
第二節 UAS航拍熱像定位定向與應用之研究 16
第三節 誤匹配點剔除 19
第四節 獲取地表溫度 21
第三章 理論基礎與研究方法 23
第一節 相機率定模式 23
一、 野外率定場法 23
二、 In-Flight Camera Calibration 26
第二節 GNSS輔助光束法空三平差理論 28
一、 GNSS動態後處理技術原理與航拍軌跡獲取方法 28
二、 GNSS輔助光束法空三平差 29
第三節 誤匹配點剔除 33
第四節 產製數值溫度表面模型 38
第四章 研究材料與實驗 39
第一節 儀器及軟體 39
一、 GNSS接收模組:BD970 39
二、 熱像儀:FLIR-TAU 640 41
三、 熱像儀 :巨哥電子XM6 42
四、 熱像儀率定軟體:iWitnessPRO 43
五、 四旋翼UAS :AI-RIDER YJ-1000-HC 44
六、 影像匹配軟體:Pix4Dmapper 45
七、 航測軟體:IMAGINE Photogrammetry 2015 & ORIMA 45
第二節 熱像儀率定實驗 47
一、 指南溪實驗區熱像前處理 47
二、 率定實驗 48
第三節 指南溪試驗區實驗 54
一、 航拍規劃 54
二、 拍攝結果 55
三、 圖4- 15 指南溪實驗區使用之熱影地面涵蓋圖UAV GNSS PPK軌跡求解 56
七、 熱像連結點匹配探討 60
八、 Pix4Dmapper光束法空三平差 63
九、 誤匹配點剔除 64
十、 ORIMA光束法空三平差 65
十一、 產製數值溫度表面模型 68
第四節 小油坑試驗區實驗 73
一、 航拍規劃 73
二、 拍攝結果 74
三、 UAV GNSS PPK軌跡求解 75
四、 Pix4Dmapper光束法空三平差 78
五、 誤匹配點剔除 79
六、 ORIMA光束法空三平差 79
七、 產製數值溫度表面模型 83
第五章 結論與建議 91
第一節 結論 91
一、 指南溪實驗區 91
二、 小油坑實驗區 93
三、 遭遇問題探討 94
四、 總結 96
第二節 建議 97
一、 三焦張量的策略 97
二、 影像擷取之時間最小單位 97
三、 地表溫度之校正 97
參考文獻 98		zh_TW
dc.format.extent 4335915 bytes-
dc.format.mimetype application/pdf-
dc.source.uri (資料來源) http://thesis.lib.nccu.edu.tw/record/#G0103257032en_US
dc.subject (關鍵詞) 無人機zh_TW
dc.subject (關鍵詞) 熱像zh_TW
dc.subject (關鍵詞) 定位定向zh_TW
dc.subject (關鍵詞) 光束法空三平差zh_TW
dc.subject (關鍵詞) 熱像儀率定zh_TW
dc.subject (關鍵詞) 三焦張量zh_TW
dc.subject (關鍵詞) Unmanned aircraft systemen_US
dc.subject (關鍵詞) Thermal imagesen_US
dc.subject (關鍵詞) Positioning and orientationen_US
dc.subject (關鍵詞) Bundle adjustment aerial triangulationen_US
dc.subject (關鍵詞) Thermal camera calibrationen_US
dc.subject (關鍵詞) Trifocal tensoren_US
dc.title (題名) 以四旋翼UAS酬載熱感測器製作數值表面溫度模型供地溫研究zh_TW
dc.title (題名) Generation of digital surface temperature model from images collected by thermal sensor on quadcopter UAS for geothermal studyen_US
dc.type (資料類型) thesisen_US
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