地景階層林地碳儲存量之估算-以花蓮光復鄉平地造林為例

Jou-Han Shen; 沈柔含

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/9914

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	邱祈榮(Chyi-Rong Chiou)
dc.contributor.author	Jou-Han Shen	en
dc.contributor.author	沈柔含	zh_TW
dc.date.accessioned	2021-05-20T20:49:08Z	-
dc.date.available	2011-08-12
dc.date.available	2021-05-20T20:49:08Z	-
dc.date.copyright	2011-08-12
dc.date.issued	2011
dc.date.submitted	2011-08-08
dc.identifier.citation	田慶久、閔祥軍. (1998). 植被指數研究進展. 地學科學進展, 13(4), 327-333. 邱祈榮. (1996). 遙測技術於水資源經營. 森林與水資源經營研討會論文集 (pp. 15-49). 李國忠、林俊成、陳麗琴. (2000). 台灣杉人工林碳吸存潛力及其成本效益分析. 台灣林業科學, 15(1), 115-123. 林金樹. (1999). 森林植生季節性光譜特性之研究. 台灣林業科學, 14(3), 289-305. 林務局. (1997). 台灣林產物處分調查用立木材積表. 林裕仁. (2005). 台灣地區木材之含碳量與比重測定. 森林經營對二氧化碳吸存之貢獻研討會論文集, 266-278. 林裕仁、劉瓊霦、林俊成. (2002). 台灣地區主要用材比重與碳含量測定. 台灣林業科學, 17(3), 291-299. 花蓮縣政府. (1995). 花蓮縣綜合發展計畫. 內政部營建署. Retrieved from http://gisapsrv01.cpami.gov.tw/cpis/cprpts/hualien/index.htm. 陳仲賢、何湘梅. (2008). 推動平地景觀造林及綠美化計劃執行成果. 農政與農情, 192. 郭鈮. (2003). 植被指數及其研究進展. 乾旱氣象, 21(4)(40375011), 72-75. 國立中央大學太空及遙測研究中心. (2010). 國立中央大學太空及遙測研究中心資源衛星接收站使用者手冊. 曾仁鍵. (2004). 衛星影像於大度山地區植被光譜變遷之監測. 國立臺灣大學. 彭炳勳、魏浚紘、陳朝圳. (2009). 應用空載光達資料推測阿里山地區單木樹高與林分高度之研究. 中華林學季刊, 42(1), 167-180. 楊榮啟、林文亮. (2003). 森林測計學. 國立編譯館. 鄭祈全、邱祈榮、陳燕章. (1997). 應用遙測方法估測台灣杉林分之葉面積指數. 台灣林業科學, 12(3), 309-317. 鄭祈全、許立達、陳燕章. (1998). 整合地理資訊系統與遙測技術於林分材積估測之研究. 台灣林業科學, 13(2), 155-167. 廖述惠、王亞男. (2002). 樟樹與台灣櫸於林下栽植二氧化碳固定效益之研究. 中華林學季刊, 35(4), 361-373. 謝漢欽. (2006). 從京都議定書看台灣的森林資源調查. 林業研究專訊, 13(1), 18-21. Avery, T. E., Berlin, G. L. L., & Berlin, G. L. (1992). Fundamentals of Remote Sensing and Airphoto Interpretation (5th ed.). New Jersey: Prentice Hall. Bonnor, G. M. (1982). Canadaʼs forest inventory (p. 79). Bonnor, G. M. (1985). Inventory of forest biomass in Canada. National Library of Australia. Brown, S., Schroederb, P., & Kernb, J. (1999). Spatial distribution of biomass in forests of the eastern USA. Forest Ecology and Management, 123(1), 81-90. DeFries, R., Hansen, M., & Townshend, J. (1995). Global discrimination of land cover types from metrics derived from AVHRR pathfinder data. Remote Sensing of Environment, 54(3), 209-222. Fournier, R. A., Luther, J. E., Guindon, L., Lambert, M.-C., Piercey, D., Hall, R. J., et al. (2003). Mapping aboveground tree biomass at the stand level from inventory information: test cases in Newfoundland and Quebec. NRC Research Press Ottawa, Canada. Goetz, A. F. H., Rock, B. N., & Rowan, L. C. (1983). Remote sensing for exploration: an overview. Econ. Geol.; (United States), 78:4. Grubb, M., Vrolijk, C., & Brack, D. (1999). The Kyoto protocol: a guide and assessment. Royal Institute of International Affairs. Hall, F., Strebel, D., Nickeson, J., & Goetz, S. (1991). Radiometric rectification: Toward a common radiometric response among multidate, multisensor images☆. Remote Sensing of Environment, 35(1), 11-27. Hoffer, R. M. (1978). Remote Sensing: The Quantitative Approach. (P. H. Swain & S. M. Davis, Eds.). New York: McGraw-Hill International Book Co. Huete, a. (1988). A soil-adjusted vegetation index (SAVI). Remote Sensing of Environment, 25(3), 295-309. Huete, a, Justice, C., & Liu, H. (1994). Development of vegetation and soil indices for MODIS-EOS. Remote Sensing of Environment, 49(3), 224-234. IPCC. (1997). Revised 1996 IPCC guidelines for national greenhouse gas inventories. Paris, France. Jensen, J. R. (1986). Introductory digital image processing: A remote sensing perspective. Prentice Hall, Inc.,Old Tappan, NJ. Jensen, J. R. (2000). Remote sensing of the environment: an earth resource perspective. Prentice-Hall. Jensen, J. R. (2007). Remote Sensing of the Environment: An Earth Resource Perspective (2nd ed.). Prentice Hall. Jiang, J.-H., Berry, R. J., Siesler, H. W., & Ozaki, Y. (2002). Wavelength Interval Selection in Multicomponet Spectral Analysis by Moving Window Partial Least-Squares Regression with Application to Mid-Infrared and Near-Infrared Spectroscopic Data. Analytical Chemistry, 74, 3555-3565. Labrecque, S., Fournier, R. A., Luther, J. E., & Piercey, D. (2006). A comparison of four methods to map biomass from Landsat-TM and inventory data in western Newfoundland. Forest Ecology and Management, 226(1-3), 129-144. Landsberg, J. J., & Waring, R. H. (1997). A generalised model of forest productivity using simplified concepts of radiation-use efficiency, carbon balance and partitioning. Forest Ecology and Management, 95(3), 209-228. Lawrence, R. L., & Ripple, W. J. (1998). Com-parisons among vegetation indices and bandwise regression in a highly disturbed, heterogeneous landscape. Remote Sensing of Environment, 64, 91-102. Liua, J., Chenb, J., Cihlarb, J., & Parkb, W. (1997). A process-based boreal ecosystem productivity simulator using remote sensing inputs. Remote Sensing of Environment, 62(2), 158-175. Myers, V. I. (1970). Soil, Water, and Plant Relations. In “Remote Sensing with Special Reference to Agriculture and Forestry” (pp. 253-297). Washington, D.C. National Academy of Sciences. Penner, M., Power, K., Muhairwe, C., Tellier, R., & Wang, Y. (1997). Canadian Forest Service Publications : Canadaʼs forest biomass resources: Deriving estimates from Canada's forest inventory. Government of Canada, Natural Resources Canada. Price, D., & Apps, M. (1996). Boreal forest responses to climate-change scenarios along an ecoclimatic transect in central Canada. Climatic Change, 34(2), 179-190-190. Springer Netherlands. Rouse, J. W., Haas, R. H., Schell, J. A., & Deering, D. W. (1974). Monitoring Vegetation Systems in the Great Plains with Erts. NASA Special Publication, 351, 309. Roy, P., & Ravan, S. (1996). Biomass estimation uaing satellite remote sensing data: an invenstigation on possible approaches for nature forest. Ecol. Manage., 123, 81-90. Solomon, A. M., & Shugart, H. H. (1993). Vegetation Dynamics And Global Change. New York (N.Y.) : Chapman and Hall.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/9914	-
dc.description.abstract	目前國內估算林分蓄積所使用多為既有樣區資料，其設置常受到可達性與調查員主觀判定之影響，導致樣區無法代表大規模林分之生長狀況。本研究目的在於改良傳統設置樣區方法，利用衛星影像發展不易受到人為主觀影響的樣區設置流程，建立以光譜資訊估算林分材積預測式，將林分蓄積結果換算為碳儲存量。研究方法為利用衛星影像光譜資訊得到全林分生長狀況之梯度，分層取樣不同生長情形之光譜樣點，並於均質區中設置樣區，進而發展光譜資訊推估林分材積之模型，藉以繪製出林分材積空間分布圖。本研究試驗地位於臺糖公司花蓮縣光復鄉之平地造林，對象為櫸樹 (Zelkova serrata (Thunb.) Makino) 與光臘樹 (Fraxinus griffithii C. B. Clarke) 之材積。檢驗資料為林業試驗所於2009 – 2010年在光復造林地設置之樣區資料。研究結果發現以NDVI光譜資訊估算林分材積(m3/ha)預測式有最高之迴歸結果 (櫸樹模式R2 =0.58；光臘樹模式R2 =0.88)，估算結果和檢核資料之間差異性不大，均在95 %信賴區間內，但略為低估。繪製之像元林分參數空間分布圖與空照圖比較對照結果發現其能清楚反應出平地造林全區的生長狀況，可做為林地經營管理參考指標。	zh_TW
dc.description.abstract	The estimation of forest growing stock is usually affected by availability and subjective determination of setting plot process, which may influence the stock estimation of growing stands. This study is aimed to improve the sampling methods avoiding anthropological affection by using spectral information from satellite images. The spectral information of satellite images was used to establish the growing gradients of target stands and the spectral plots were sampled from each stage of growth. Therefore, the spectral plots were selected from homogenous zones to setup ground plots and develop the stand volume model to estimate forest growing stock and spatial distribution of stand volume. The target stand is the Taiwan Sugar Cooperation afforestation of Zelkova (Zelkova serrata (Thunb.) Makino) and Formosan ash (Fraxinus griffithii C. B. Clarke) located at Guangfu Township, Hualien County. The validation dataset is the sampling data investigated by Taiwan Forest Research Institute during 2009–2010. The result shows that the NDVI spectral data estimating the stand volume has the highest performance among regression models (Zelkova model R2 =0.58, Formosan ash R2 =0.88). The estimating results were within 95% confidence interval, slightly underestimated. However, comparing the pixel spatial distribution of forest stand parameters and the aerial photographs, it clearly reflects the growth status of afforestation, which would be a good indicator for forest management.	en
dc.description.provenance	Made available in DSpace on 2021-05-20T20:49:08Z (GMT). No. of bitstreams: 1 ntu-100-R98625016-1.pdf: 14924455 bytes, checksum: ec71fadb2b25af61f6524cb7bd11bd4b (MD5) Previous issue date: 2011	en
dc.description.tableofcontents	口試委員會審定書 i 致謝 ii 摘要 iv ABSTRACT v 目錄 vi 圖目錄 ix 表目錄 xi 壹、前言 1 貳、文獻回顧 4 一、遙測技術 4 二、植物光譜特性 5 三、雙光譜圖 7 四、植生指數 8 參、材料與方法 10 一、研究材料 10 （一）研究地區環境概述 10 （二）衛星影像 12 （三）臺糖公司造林地資料 16 1. 初期收集資料 16 (1) 造林地範圍圖框 16 (2) 臺糖公司造林地基本資料 17 2. 造林小區境界測量 19 （四）地真資料 23 二、研究流程 24 三、研究方法 25 （一）光譜均質分析 25 （二）利用雙光譜圖選取光譜樣點 26 （三）地面樣區位置規劃 26 （四）地面樣區 27 1. 確定樣區預定位置 27 2. 樣區設置 27 3. 調查項目 28 (1) 樣區四角位置定位 29 (2) 現地狀況調查 29 (3) 每木調查 29 4. 林分參數計算 30 (1) 林分覆蓋率 30 (2) 栽植株數與栽植密度 30 (3) 成活株數與成活率 30 (4) 林分密度 30 (5) 單木材積 31 (6) 林分材積 31 四、光譜資訊估測林分材積模式之建立 32 五、碳儲存量轉換方法 33 肆、結果與討論 34 一、光譜樣區規劃 34 （一）光譜均質區 34 （二）光譜樣點 35 1. 雙光譜圖分布 35 2. 光譜樣點選擇 36 （三）光譜樣區預定位置 38 二、樣區地面林分參數資料 40 三、光譜資訊與林分參數迴歸分析 44 1. R波段迴歸結果 45 2. NIR波段迴歸結果 46 3. NDVI值迴歸結果 47 4. SAVI值迴歸結果 48 四、估算結果檢核與樣區比較 50 （一）評估樣區檢核結果 50 （二）評估樣區與光譜樣區林分參數比較 52 （三）估算結果 55 五、林分參數空間分布圖 57 六、碳儲存量轉換結果 68 伍、結論 69 參考文獻 71 附錄一 75 附錄二 76 附錄三 79
dc.language.iso	zh-TW
dc.title	地景階層林地碳儲存量之估算-以花蓮光復鄉平地造林為例	zh_TW
dc.title	Estimation of Carbon Storage at Landscape Level – a Case Study of Lowland Plantation at Guangfu, Hualian	en
dc.type	Thesis
dc.date.schoolyear	99-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	邱志明(Chih-Ming Chiu),林世宗(Shu-Tzong Lin),顏添明(Tian-Ming Yen)
dc.subject.keyword	碳儲存量,林分蓄積,平地造林,衛星遙測,	zh_TW
dc.subject.keyword	Carbon storage,stand volume,lowland plantation,remote sensing,	en
dc.relation.page	79
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2011-08-08
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	森林環境暨資源學研究所	zh_TW
顯示於系所單位：	森林環境暨資源學系

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