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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 趙鍵哲(Jen-Jer Jaw) | |
dc.contributor.author | Yong-Yao Lan | en |
dc.contributor.author | 藍雍堯 | zh_TW |
dc.date.accessioned | 2021-06-16T17:51:48Z | - |
dc.date.available | 2021-02-22 | |
dc.date.copyright | 2021-02-22 | |
dc.date.issued | 2021 | |
dc.date.submitted | 2021-02-03 | |
dc.identifier.citation | Geng, J., 2011. Structured-light 3D surface imaging: a tutorial. Advances In Optics And Photonics, 3(2), pp. 128-160. Kazó, C., Hajder, L., 2012. High-quality structured-light scanning of 3D objects using turntable. 3rd IEEE International Conference on Cognitive Infocommunications , pp. 553-557. Koutsoudis, A., Vidmar, B., Arnaoutoglou, F., 2013. Performance evaluation of a multi-image 3D reconstruction software on a low-feature artefact. Journal of Archaeological Science, 40(12), pp. 4450-4456. Liu, Y. L., Lin, T. H., 2018. Feature enhancement for a defocusing structured-light 3-D scanning system. Optical Engineering, 57(6), 064101. Menna, F., Nocerino, E., Morabito, D., Farella, E. M., Perini, M., Remondino, F., 2017. An Open Source Low-Cost Automatic System for Image-Based 3d Digitization. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, pp.155-162. Nguyen, C. V., Fripp, J., Lovell, D. R., Furbank, R., Kuffner, P., Daily, H., Sirault, X., 2016. 3D scanning system for automatic high-resolution plant phenotyping. In Digital Image Computing: Techniques and Applications (DICTA), 2016 International Conference on , pp. 1-8. Nicolae, C., Nocerino, E., Menna, F., Remondino, F., 2014. Photogrammetry applied to problematic artefacts. The International Archives of Photogrammetry, Remote Sensing and Spatial Information Sciences, 40(5). Nie, L., Ye, Y., Song, Z., 2017. Method for calibration accuracy improvement of projector-camera-based structured light system. Optical Engineering, 56(7). Nocerino, E., Menna, F., Remondino, F., Beraldin, J. A., Cournoyer, L., Reain, G., 2016. Experiments On Calibrating Tilt-Shift Lenses For Close-Range Photogrammetry. International Archives of the Photogrammetry, Remote Sensing Spatial Information Sciences, 41. Pacheco, A., Baron, H. B., Crespo, R. G., Espada, J. P., 2014. Reconstruction of High Resolution 3D Objects from Incomplete Images and 3D Information. IJIMAI, 2(6), 7-16. Patil, H.,Kothari, A., Bhurchandi, K., 2015. 3-D face recognition: features, databases, algorithms and challenges, Artificial Intelligence Review, 44(3), pp. 393-441. Pusztai, Z., Hajder, L., 2016. A turntable-based approach for ground truth tracking data generation. VISAPP, pp. 498-509. Schaich, M., 2013. Combined 3D scanning and photogrammetry surveys with 3D database support for archaeology cultural heritage – A practice report on ArcTron's information system aSPECT3D, Photogrammetric Week 2013, pp. 233-246. Sobani, S. S. M., Daud, S. A., Mahmood, N. H., 2013. Preliminary Study Of Multi-View Imaging For Accurate 3d Reconstruction Using Structured Light Scanner. International Journal of Research in Engineering and Technology,02(10), pp. 235-238. TEXAS INSTRUMENTS., 2018. Support training, TI Training, Live training, URL: https://training.ti.com/search-catalog/type/classroom/type/webcast. (last date accessed: Oct 18, 2018) 车向前,2008。结构光三维测量系统中匹配与拼合技术研究,碩士論文,哈尔滨工程大学。 台灣儀器行,2018。產品服務,URL:http://www.ticgroup.com.tw,台灣儀器行股份有限公司,台北市。(最後取用時間:2018 年11 月16 日) 白紹翊,2012。結構光條紋視覺系統之表面量測,中華大學機械工程學系碩士論文。 李建樟,2012。測繪文物數位典藏方法之研究,碩士論文,國防大學工學院環境資訊及工程學系空間科學碩士班,桃園市。 李彩林,2015。基于结构光的手持式摄影扫描系统关键技术研究,测绘学报, (4) ,472-472。 林宏明,2006。以近景攝影進行圓柱試體變位之量測,岩盤工程研討會論文集,台南,頁589-598。 張鈞傑,2006。任意頻率調變式雷射測距儀,碩士論文,中央大學光電科學研究所,桃園市,頁1-97。 梁福榮,2006。攝影測量應用於古蹟記錄和邊坡表面變化量量測之研究,碩士論文,成功大學土木工程學系,成功大學,台南市,頁1-120。 廖彥舒,2004。非量測型數位相機應用於近景攝影測量之研究─使用三~六百萬畫素相機,碩士論文,逢甲大學土地管理學系碩士在職專班,台中市。 蔡育霖、陳俊宇、何佩真,2016.三維建模技術於出水遺物保存維護工作之應用案例探討,文化財產保存學刊,第37 期,頁41-58。 | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/64515 | - |
dc.description.abstract | 測量是一門幾何描繪及分析應用的學科,為能描繪世界樣貌、記錄事物,重建立體世界的方法有手繪、影像、二維圖形以及三維點雲等,與時俱進的測量技術提升測量的工具、成果與精度。 幾何重建為測量常態性任務,常見的三維建模方式,如接觸式掃描儀、雷射掃描儀、結構光以及攝影測量,各有其作業方便性及限制性。其中針對小型可移動式物件,利用旋轉台提供穩定的旋轉系統,利用旋轉改變測量儀器與目標物之間的相對位置,加上自動化擷取、靈活配置以及低成本的作業方法,經常搭配攝影測量進行三維物件重建,惟攸關重建品質的取像作業參數尚未有一套優化程序可供參照。 本研究透過推導地面取樣距離、景深與透鏡成像公式之參數關係,以及模擬旋轉台拍攝之實驗,建構一套以攝影測量搭配旋轉台的三維物件重建取像優化程序,協助使用者作業前便能依據處理類型並使用相應公式建構查照表格,從中決定取像前所需配置之攝影參數,依循清晰流程與簡要設定,獲取清晰影像,完成三維物件重建取像作業,進而獲得完整且忠實呈現物體幾何的重建結果。 | zh_TW |
dc.description.abstract | Survey is the discipline of geometric description and analysis application. The methods to describe the world, record the things, and reconstruct the world include hand-painted, images, 2D graphics, to 3D point clouds. The measurement technique improves the tools, results and precision with the times. Geometric reconstruction is a normal task of measurement. Common 3D modeling instruments, such as coordinate measuring machine, laser scanner, structured light system and photogrammetry, each have their own convenience and limitations. Among them, for small movable objects, the turntable provides a stable rotation system, which uses rotation to change the relative position between the measuring instrument and the target. It is an automatic acquisition, flexible configuration, and low-cost operation method and often used with photogrammetry for 3D object reconstruction. There is not yet a set of optimization procedures for reference of operating parameters related to reconstruction quality. In this study, by deriving the parameter relationship between depth of field (DOF), Ground sample distance (GSD) and lens imaging formula, as well as simulating the experiment of turntable, we want to construct a set of 3D object reconstruction and imaging optimization program with photogrammetry and turntable. Before assisting users to work, they can construct a photo search form according to the processing type and use the corresponding formula. From this, determine the photography parameters that need to be configured before taking the image, follow clear procedures and brief settings, get clear images, and complete the 3D object reconstruction and acquisition operation, then obtain a complete and faithful reconstruction result of the object geometry. | en |
dc.description.provenance | Made available in DSpace on 2021-06-16T17:51:48Z (GMT). No. of bitstreams: 1 U0001-0202202117210700.pdf: 12991639 bytes, checksum: e9f027be8f8c3f899880fee477d51a55 (MD5) Previous issue date: 2021 | en |
dc.description.tableofcontents | 誌謝 i 中文摘要 ii Abstract iii 目錄 iv 圖目錄 vii 表目錄 xi 第一章 緒論 1 1.1 前言 1 1.2 研究動機與目的 1 1.3 研究方法與流程 2 1.4 論文架構 3 第二章 文獻回顧 4 2.1 三維建模工具 4 2.1.1 三坐標測量儀(Coordinate Measuring Machine, CMM) 4 2.1.2 雷射掃描儀(Laser Scanner) 4 2.1.3 結構光(Structured Light) 5 2.1.4 攝影測量(Photogrammetry) 6 2.2 旋轉台(Turntable) 6 2.3 三維建模技術與儀器之比較 9 2.4 小結 11 第三章 研究方法 12 3.1 基於旋轉台利用攝影測量拍攝之實驗配置 12 3.2 景深 15 3.3 旋轉台參數 20 3.4 問題處理一(已知GSD 與像主距,求物體尺寸與物距) 22 3.4.1 推導過程 22 3.4.2 GSD、像主距、物體尺寸、最遠物距之關係 24 3.5 問題處理二(已知GSD 與物體尺寸,求像主距與物距) 27 3.5.1 推導過程 27 3.5.2 GSD、像主距、物體尺寸、最遠物距之關係 29 3.6 問題處理三(固定最遠物距與像主距,求GSD 與物體尺寸) 31 3.6.1 推導過程 31 3.6.2 GSD、像主距、物體尺寸、最遠物距之關係 32 3.7 參數測試成果 35 3.7.1 微調參數彈性空間 35 3.7.2 實際設定參數拍攝 38 3.8 小結 43 第四章 模擬實驗 44 4.1 模擬實驗一(目標物幾何重心對準旋轉台軸心) 44 4.1.1 情況1(圓柱體,投影形狀:圓形) 46 4.1.2 情況2(三角柱,投影形狀:正三角形) 48 4.1.3 情況3(四角柱,投影形狀:正方形) 52 4.1.4 情況4(五角柱,投影形狀:正五邊形) 56 4.1.5 情況5(六角柱,投影形狀:正六邊形) 60 4.1.6 情況6(三角柱,投影形狀:直角三角形) 64 4.1.7 情況7(四角柱,投影形狀:寬20mm 長方形) 68 4.1.8 情況8(四角柱,投影形狀:寬40mm 長方形) 72 4.1.9 情況9(四角柱,投影形狀:寬60mm 長方形) 76 4.1.10 情況10(四芒星柱,投影形狀:四芒星) 80 4.1.11 情況11(五芒星柱,投影形狀:五芒星) 84 4.1.12 情況12(六芒星柱,投影形狀:六芒星) 88 4.1.13 小結(模擬實驗一) 92 4.2 模擬實驗二(非對稱角柱偏移旋轉台軸心) 93 4.2.1 情況1(三角柱,投影形狀:直角三角形) 93 4.2.2 小結(模擬實驗二) 96 4.3 模擬實驗三(圓柱體偏移旋轉台軸心) 97 4.3.1 情況1(圓柱體投影形狀外心偏移旋轉台軸心5mm) 97 4.3.2 情況2(圓柱體投影形狀外心偏移旋轉台軸心25mm) 101 4.3.3 情況3(圓柱體投影形狀外心偏移旋轉台軸心45mm) 105 4.3.4 小結(模擬實驗三) 109 第五章 實際拍攝成果 110 5.1 情況1(目標物幾何重心對準旋轉台軸心拍攝各類角柱) 113 5.2 情況2(不同像主距設定拍攝圓柱體) 121 5.3 情況3(使圓柱體逐漸偏離旋轉台軸心拍攝) 127 5.4 情況4(以不同姿態拍攝角柱) 135 5.5 情況5(傾斜角度拍攝目標物) 140 5.6 小結 6.1 結論 145 6.2 未來展望 147 參考文獻 148 附錄 151 | |
dc.language.iso | zh-TW | |
dc.title | 基於旋轉台的三維物件重建物像配置優化作業 | zh_TW |
dc.title | Optimization of Image Acquisition for Turntable-based Photogrammetric 3D Object Reconstruction | en |
dc.type | Thesis | |
dc.date.schoolyear | 109-1 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 邱式鴻(Shih-Hong Chio),莊子毅(Zi-Yi Chuang) | |
dc.subject.keyword | 攝影測量,三維建模,物件重建,旋轉台,優化程序, | zh_TW |
dc.subject.keyword | Photogrammetry,3D Modeling,Reconstruction,Turntable,Optimization, | en |
dc.relation.page | 154 | |
dc.identifier.doi | 10.6342/NTU202100404 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2021-02-04 | |
dc.contributor.author-college | 工學院 | zh_TW |
dc.contributor.author-dept | 土木工程學研究所 | zh_TW |
顯示於系所單位: | 土木工程學系 |
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