整合地理統計及資料同化方法於水文地質架構推估與地下水模型建立-以濁水溪沖積扇為例

蘇逸; Yi Su

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/97118

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	余化龍	zh_TW
dc.contributor.advisor	Hwa-Lung Yu	en
dc.contributor.author	蘇逸	zh_TW
dc.contributor.author	Yi Su	en
dc.date.accessioned	2025-02-27T16:16:38Z	-
dc.date.available	2025-02-28	-
dc.date.copyright	2025-02-27	-
dc.date.issued	2025	-
dc.date.submitted	2025-02-08	-
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Getis (Eds.), Handbook of Applied Spatial Analysis: Software Tools, Methods and Applications (pp. 461-486). Springer Berlin Heidelberg. https://doi.org/10.1007/978-3-642-03647-7_22 Xie, J., Huang, J., Zeng, C., Huang, S., & Burton, G. J. (2022). A generic framework for geotechnical subsurface modeling with machine learning. Journal of Rock Mechanics and Geotechnical Engineering, 14(5), 1366-1379. https://doi.org/https://doi.org/10.1016/j.jrmge.2022.08.001 Zhang, J., Ma, X., Zhang, J., Sun, D., Zhou, X., Mi, C., & Wen, H. (2023). Insights into geospatial heterogeneity of landslide susceptibility based on the SHAP-XGBoost model. Journal of environmental management, 332, 117357. Zhang, Z., Wang, G., Carranza, E. J. M., Liu, C., Li, J., Fu, C., Liu, X., Chen, C., Fan, J., & Dong, Y. (2023). An integrated machine learning framework with uncertainty quantification for three-dimensional lithological modeling from multi-source geophysical data and drilling data. Engineering Geology, 324, 107255. 吳孟庭、林遠見、余化龍。(2016)。資料不確定下之地質岩性推估－以臺北盆地為例 [Uncertainty Analysis of Lithological Classification in Taipei Basin]。農業工程學報，62(4)，21-37。https://doi.org/10.29974/jtae.201612_62(4).0002 林廷安。(2022)。整合地理統計與機器學習方法於水文地質架構推估與模擬-以蘭陽平原為例 [碩士論文，國立臺灣大學]。臺灣博碩士論文知識加值系統。臺灣。https://hdl.handle.net/11296/4d9g8v 經濟部中央地質調查所。(2017)。地下水水文地質與水資源調查 - 地下水庫活化與效益評估 (1/4)。https://twgeoref.gsmma.gov.tw/GipOpenWeb/wSite/ct?xItem=217406&ctNode=289&mp=6	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/97118	-
dc.description.abstract	在環境科學與工程應用等領域，受限於操作條件、經費或自然干擾，常面臨觀測資料不足及空間解析度不足的問題，對區域特性研究造成挑戰。濁水溪沖積扇作為台灣重要的農業重鎮，具有複雜的地質條件與地下水分布，且頻繁出現地層下陷與鹹水入侵等問題，對該區域地下水資源的管理與評估提出了更高的要求。因此，掌握其水文地質架構並建立可靠的地下水模型成為緩解地層下陷及管理的基礎。本研究旨在推估濁水溪沖積扇的三維水文地質架構及分層水力傳導係數場，並進一步以資料同化精進模擬地下水流動的模型。首先，基於有限的水文地質剖面資料、岩性鑽探資料及三維電阻率模型等多種資料，採用eXtreme Gradient Boosting(XGBoost)推估濁水溪沖積扇的三維岩性機率場，作為後續建模的不確定性資料。接著，透過類別型貝氏最大熵法(Categorical BME)，結合以上資料建立完整的三維岩性推估模型，得到細緻的三維岩性場，並且進一步以核密度估計與資料科學方法為地下水模型進行精確分層。隨後，為了進行分層水力傳導係數的推估，本研究應用連續型貝氏最大熵法(Continuous BME)，結合地理加權迴歸(Geographically Weighted Regression, GWR)，利用岩性及地球物理數據建立含水層的水力傳導係數場模型。在建立地下水模型階段，本研究採使用MODFLOW模擬地下水流動過程，並運用集合平滑器(Ensemble Smoother, ES)進行參數資料同化。此方法通過動態更新參數(如抽水補注量及水力傳導係數)，有效整合觀測數據與模型結果，顯著提升模擬精度，同時減少傳統參數率定過程的時間成本。本研究不僅解決了區域地質結構的推估難題，亦探索了以自動化方式結合多源資料與物理模型的潛力，期望能為地層下陷的防治及地下水資源的永續管理提供參考與支持。	zh_TW
dc.description.abstract	In the fields of environmental science and engineering applications, the lack of observational data and insufficient spatial resolution, often constrained by operational conditions, budget limitations, or natural interferences, poses challenges to regional characteristic studies. The Choshui River alluvial fan, a critical agricultural region in Taiwan, exhibits complex geological conditions and groundwater distribution. It frequently experiences land subsidence and seawater intrusion, raising the demands for effective management and assessment of groundwater resources. Therefore, understanding its hydrogeological framework and establishing a reliable groundwater model forms the foundation for mitigating land subsidence and optimizing resource management. This study aims to estimate the three-dimensional hydrogeological framework and stratified hydraulic conductivity field of the Choshui River alluvial fan, further enhancing the simulation of groundwater flow through data assimilation. First, using limited hydrogeological profile data, lithological drilling data, and a three-dimensional resistivity model, eXtreme Gradient Boosting (XGBoost) was applied to estimate the three-dimensional lithological probability field of the Choshui River alluvial fan, providing soft data for subsequent modeling. Subsequently, the categorical Bayesian Maximum Entropy (Categorical BME) method was employed to integrate the above data and establish a comprehensive three-dimensional lithological estimation model, resulting in a detailed three-dimensional lithological field. Furthermore, kernel density estimation and data science methods were applied to achieve accurate stratification for the groundwater model. Next, to estimate the stratified hydraulic conductivity, the study applied the continuous Bayesian Maximum Entropy (Continuous BME) method, combined with Geographically Weighted Regression (GWR), to construct a hydraulic conductivity field model for aquifers using lithological and geophysical data. During the groundwater modeling phase, MODFLOW was utilized to simulate groundwater flow processes, and the Ensemble Smoother (ES) was employed for parameter data assimilation. This approach dynamically updated parameters (e.g., pump discharge, recharge and hydraulic conductivity), effectively integrating observational data with model results, significantly enhancing simulation accuracy while reducing the computational cost of traditional parameter calibration processes. This study not only addresses the challenges in estimating regional geological structures but also explores the potential of integrating multi-source data with physical models using automated approaches. The findings are expected to contribute to the prevention of land subsidence and the sustainable management of groundwater resources.	en
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dc.description.tableofcontents	論文口試委員會審定書 I 謝辭 II 摘要 III Abstract IV 目次 VI 圖次 X 表次 XV Chapter1. 緒論 1 1.1 研究目的 1 1.2 論文架構 2 1.3 研究架構 3 1.4 文獻回顧 5 1.4.1 eXtreme Gradient Boosting 5 1.4.2 貝氏最大熵法 6 1.4.3 集合平滑器 7 1.4.4 三維岩性場及水力傳導係數場推估 8 Chapter2. 研究區域與理論 11 2.1 研究區域介紹 11 2.2 eXtreme Gradient Boosting 12 2.2.1 正則化學習目標 12 2.2.2 梯度樹提升 13 2.2.3 收縮與列抽樣 15 2.2.4 精確貪婪算法 15 2.2.5 近似演算法 15 2.2.6 稀疏感知分裂點查找法 16 2.3 類別型隨機場 17 2.3.1 類別型隨機場之共變異函數和變異圖 17 2.4 貝氏最大熵法(BME) 19 2.4.1 類別型貝氏最大熵法之聯合機率密度 20 2.4.2 類別型貝氏最大熵法之後驗條件機率分佈 21 2.4.3 連續型貝氏最大熵法 22 2.5 SPOTPY 24 2.6 核密度估計(Kernel Density Estimation) 25 2.7 地理加權迴歸(Geographically Weighted Regression) 26 2.8 集合平滑器(Ensemble Smoother) 29 Chapter3. 以XGBoost推估濁水溪沖積扇岩性機率場 32 3.1 資料前處理 32 3.1.1 XGBoost模型訓練資料 33 3.1.2 XGBoost模型測試資料 46 3.1.3 XGBoost模型預測點資料 50 3.2 研究結果展示與分析 50 3.2.1 XGBoost模型參數優化與驗證 51 3.2.2 XGBoost模型測試 53 3.2.3 XGBoost模型預測結果展示 64 Chapter4. 以類別型BME推估濁水溪沖積扇岩性場 66 4.1 資料前處理 66 4.1.1 岩心鑽探資料 66 4.1.2 水文地質剖面資料 67 4.1.3 XGBoost岩性場資料 69 4.2 研究結果展示與分析 74 4.2.1 類別型BME一般知識庫建立 74 4.2.2 類別型BME岩心推估交叉驗證 79 4.2.3 類別型BME岩性場推估 85 Chapter5. 應用自動化岩性分層於濁水溪沖積扇 92 5.1 資料前處理 92 5.2 研究結果展示與分析 95 5.2.1 阻水層邊界搜索 95 5.2.2 分層結果展示剖面 104 5.2.3 後續模型網格建立 105 Chapter6. 以連續型BME推估濁水溪沖積扇K場 109 6.1 資料前處理 109 6.1.1 現地水力傳導係數資料 109 6.1.2 地球物理資料與岩性資料 111 6.2 研究結果展示與分析 112 6.2.1 連續型BME一般知識庫建立 112 6.2.2 以地理加權迴歸建立不確定性資料 115 6.2.3 連續型BME水力傳導係數推估交叉驗證 117 6.2.4 連續型BME水力傳導係數場推估 118 Chapter7. 以集合平滑器進行地下水模型資料同化 121 7.1 地下水模型建構與資料前處理 121 7.1.1 模型基礎設置、網格與條件 121 7.1.2 水文參數與抽水補注量設定 124 7.2 研究結果展示與分析 127 7.2.1 地下水位資料 127 7.2.2 抽水補注值之資料同化 128 7.2.3 水力傳導係數之資料同化 130 7.2.4 資料同化與最終模擬結果 131 Chapter8. 研究結論與建議 135 8.1 第三章之結論與建議 135 8.2 第四章之結論與建議 135 8.3 第五章之結論與建議 136 8.4 第六章之結論與建議 136 8.5 第七章之結論與建議 137 8.6 整體結論與建議 138 Chapter9. 參考文獻 139	-
dc.language.iso	zh_TW	-
dc.subject	貝氏最大熵法	zh_TW
dc.subject	濁水溪沖積扇	zh_TW
dc.subject	水文地質架構	zh_TW
dc.subject	集合平滑器	zh_TW
dc.subject	地下水模型分層	zh_TW
dc.subject	eXtreme Gradient Boosting	zh_TW
dc.subject	Groundwater model stratification	en
dc.subject	Hydrogeological framework	en
dc.subject	Choshui River alluvial fan	en
dc.subject	Bayesian Maximum Entropy	en
dc.subject	eXtreme Gradient Boosting	en
dc.subject	Ensemble Smoother	en
dc.title	整合地理統計及資料同化方法於水文地質架構推估與地下水模型建立-以濁水溪沖積扇為例	zh_TW
dc.title	Integrating Geostatistics and Data Assimilation for Hydrogeological Structure Estimation and Groundwater Model Development: A Case Study in Choshui River Alluvial Fan	en
dc.type	Thesis	-
dc.date.schoolyear	113-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	蔡瑞彬;羅偉誠;陳主惠	zh_TW
dc.contributor.oralexamcommittee	Jui-Pin Tsai;Wei-Cheng Lo;Chu-Hui Chen	en
dc.subject.keyword	eXtreme Gradient Boosting,貝氏最大熵法,地下水模型分層,集合平滑器,水文地質架構,濁水溪沖積扇,	zh_TW
dc.subject.keyword	eXtreme Gradient Boosting,Bayesian Maximum Entropy,Groundwater model stratification,Ensemble Smoother,Hydrogeological framework,Choshui River alluvial fan,	en
dc.relation.page	143	-
dc.identifier.doi	10.6342/NTU202500481	-
dc.rights.note	同意授權(全球公開)	-
dc.date.accepted	2025-02-10	-
dc.contributor.author-college	生物資源暨農學院	-
dc.contributor.author-dept	生物環境系統工程學系	-
dc.date.embargo-lift	2030-02-07	-
顯示於系所單位：	生物環境系統工程學系

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