應用無線電遙測技術及遺傳規劃法探討大屯溪台灣鏟頷魚日間活動性與流量水溫之關係

Chin-Feng Kuo; 郭晉峰

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/66242

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	林裕彬(Yu-Pin Lin)
dc.contributor.author	Chin-Feng Kuo	en
dc.contributor.author	郭晉峰	zh_TW
dc.date.accessioned	2021-06-17T00:26:57Z	-
dc.date.available	2013-03-19
dc.date.copyright	2012-03-19
dc.date.issued	2012
dc.date.submitted	2012-02-15
dc.identifier.citation	1.Alexandre L.Godinho, Boydk Kynard.(2006) Migration and Spawning of Radio-Tagged Zulega Prochilodus argenteus in a Dammed Brazilian River. Transactions of the American Fisheries Society. 135, 811-824. 2.Allouche, S., The´venet, A., Gaudin, P. (1999) Habitat use by chub[Leuciscus cephalus (L.)] in a large river, the French Upper Rhoˆne, as determined by radiotelemetry. Archiv Fur Hydrobiologie. 145, 219-236. 3.Baade, U., Fredrich, F. (1998) Movement and pattern of activity of the roach in the River Spree, Germany. Journal of Fish Biology. 52, 1165-1174 4.Boujard, T. (1995) Diel rhythms of feeding activity in the European catﬁsh, Silurus glanis. Physiology & Behavior. 58, 641-645. 5.Bridger, C.J., Booth, R.K. (2003) The Effects of Biotelemetry Transmitter Presence and Attachment Procedures on Fish Physiology and Behavior. Reviews in Fisheries Science. 11, 13-34. 6.Brown, J. H. (1984) On the relationship between abundance and distribution of species. The American Naturalist 124, 255-279. 7.Brown, R.S., Cooke, S.J., Anderson, W.G. and McKinley , R.S. (1999) Evidence to challenge the “2% Rule” for biotelemetry. North American Journal of Fisheries Management. 19, 867-871. 8.Bruno O. David,Gerard P. Closs. (2003) Seasonal variation in diel activity and microhabitat use of an endemic New Zealand stream-dwelling galaxiid ﬁsh. Freshwater Biology. 48,1765-1781. 9.Christopher M. Bunt , Steven J. Cooke and David P. Philipp. (2003) A Modiﬁed Downrigger for Detecting Radio Transmitters in Deep Water. North American Journal of Fisheries Management 23, 258–263. 10.Clapp, D. F., Clark, R. D. Jr & Diana, J. S. (1990) Range, activity, and habitat of large, free-ranging brown trout in a Michigan stream. Transactions of the American Fisheries Society. 119, 1022-1034. 11.Clint C. Muhlfeld, Brian Marotz. (2005) Seasonal Movement and Habitat Use by Subadult Bull Trout in the Upper Flathead River System, Montana. North American Journal of Fisheries Management. 25, 797-810. 12.Cowx, I. G., Welcomme, R. L. (Eds) . (1998) Rehabilitation of rivers for fish. FAO and Fishing News Books, Blackwell Science Ltd,Oxford, 260 pp. 13.Dana K. Sackett, Kenneth W. Able, Thomas M. Grothues. (2007) Dynamics of summer ﬂounder, Paralichthys dentatus,seasonal migrations based on ultrasonic telemetry. Estuarine, Coastal and Shelf Science. 74, 119-130. 14.David, B. O. , Closs G. P. (2001) Continuous remote monitoring of fish activity with restricted home ranges using radiotelemetry. Journal of Fish Biology. 59, 705-715. 15.Enders, E. C. Smokorowski, K. E. Pennell, C. J. Clarke, K. D. Sellars, B. and Scruton, D. A. (2007) Habitat use and fish activity of landlocked Atlantic salmon and brook charr in a newly developed habitat compensation facility. Hydrobiologia. 371/372, 249-262. 16.Gaston, K. J. (1990) Patterns in the geographical ranges of species. Biological Review. 65, 105-129. 17.Geers, R., Puers, B., Goedseels, V. and Wouters, P. (1997) Electronic Identification, Monitoring and Tracking of Animals. CAB International, United Kingdom. 268 pp 18.Gorman, O. T. (1986) Assemblage organization of stream fishes: the effect of rivers on adventitious streams. The American Naturalist. 128, 611-616 19.Gorman, O. T., Karr, J. R.(1978) Habitat structure and stream fish communities. Ecology 59, 507-515. 20.Grossman G.D., Rincon P.A., Farr M.D. & Ratajczak R.E. (2002) A new optimal foraging model predicts habitat use by drift-feeding stream minnows. Ecology of Freshwater Fish.11, 2-10. 21.Hart, L. G., Summerfelt, R. C. (1975) Surgical procedures for implanting ultrasonic transmitters into flathead catfish (Pylodictus olivaris). Transactions of the American Fisheries Society. 104,56–59. 22.Harvey, B. C. , Nakamoto R. J. (1999) Diel and seasonal movements by adult Sacramento pikeminnow (Ptychocheilus grandis) in the Eel River, northwestern California. Ecology of Freshwater Fish. 8, 209-215. 23.Heggenes J., Krog O.M.W., Lindas O.R., Dokk J.G. &Bremnes T. (1993) Homeostatic behavioural responses in a changing environment: brown trout (Salmo trutta) become nocturnal during winter. Journal of Animal Ecology. 62, 295–308. 24.Hiscock, M. J., Scruton, D. A., Brown, J. A. and Pennell, C. J. (2002) Diel activity pattern of juvenile Atlantic salmon (Salmo salar) in early and late winter. Hydrobiologia. 483, 161-165. 25.Horky´ P. , Slavı´k O. , Bartosˇ L. , Kola´rˇova´ J. and Randa´k T. (2007)Behavioural pattern in cyprinid fish below a weir as detected by radio telemetry. Journal of Applied Ichthyology. 23, 679-683. 26.Howell , P. J. , Dunham , J. B. and Sankovich , P. M. (2010) Relationships between water temperatures and upstream migration, cold water refuge use, and spawning of adult bull trout from the Lostine River, Oregon, USA. Ecology of Freshwater Fish.19, 96-106. 27.Hughes N.F. (1998) A model of habitat selection by drift-feeding stream salmonids at different scales. Ecology. 79, 281–294. 28.Huryn. (1998) Ecosystem-level evidence for top-down and bottom-up control of production in a grassland stream system. Oecologia. 115, 172-183 29.Kaarina Kauhala , Thea Tiilikainen. (2002) Radio location error and the estimates of home-range size, movements, and habitat use: a simple ﬁ eld test. Annales zoological Fennici. 39, 317-324. 30.Karen J.Murchie , Karen E.Smokorowski. (2004) Relative Activity of Brook Trout and Walleyes in Response to Flow in a Regulated River. North American Journal of Fisheries Management. 24, 1050-1057. 31.Koza, J. R. (1994) Genetic Programming: Automatic Discovery of Reusable Programs Ⅱ, MIT Press, Cambridge, Massachusetts. 32.Lin, Y.S., Taso, S.S. and Chang, K.H. (1990) Population and distribution of the Formosan landlocked salmon(Oncorhynchus masou formosanus) in Chichiawan Stream. Bulletin of the Institute of Zoology, Academia Sinica. 29, 73-85. 33.Lucas, Batley. (1996) Seasonal movements and behaviour of adult barbel Barbus barbus, a riverine cyprinid ﬁsh: implications for river management. Journal of Applied Ecology. 33, 1345–1358. 34.Manteifel, B. P., Girsa, I. I. & Pavlov, D. S. (1978) On rhythms of fish behaviour. In Rhythmic Activity of Fishes (Thorpe, J. E., ed.). 215–224. London: Academic Press. 35.Marking, L.L., Meyer, F.P. (1985) Are better anesthetics needed in fisheries? Fisheries. 10, 2-5. 36.Martyn C. Lucas , Emma Batley. (1996) Seasonal movements and behaviour of adult barbel Barbus barbus, a riverine cyprinid fish: implications for river management. Journal of Applied Ecology. 33, 1345-1358. 37.Mason, J. C., Machidori, S. (1976) Populaations of sympatric sculpins, Cottus alerticus and Cottus asper, in four adjacent salmon-producing coastal streams on Vanocouter Island, B.C.U.S. Fisheries Bulletin. 74, 131-141. 38.Metcalfe, N. B., Fraser, N. H. C.and Burns, M. D. (1998) State dependent shifts between nocturnal and diurnal activity in salmon. The Royal Society .265, 1503–1507. 39.Michael, J. H. Jr. (1983) Contribution of cuttrout in headwater stream to the sea-run population. Califonia Fish and Game. 69, 68-76. 40.Mitsch, W. F. , Jorgensen S. E. (1989) Ecological Engineering. John Wiley & Sons, Inc. 41.Mitson, R. B. (1978) A review of biotelemetry techniques using acoustic tags. Rhythmic activities of fishes. Academic Press, New York.269-283.in J. E. Thorpe, editor. 42.Perry, R.W., Adams,N.S. and Rondorf, D.W. (2001) Buoyancy compensation of juvenile chinook salmon implanted with two different size dummy transmitters. American Fisheries Society. 130, 46-52. 43.Petering, R. W., Johnson, D. L. (1991) Suitability of a cyanoacrylate adhesive to close incisions in black crappies used in telemetry studies. Transactions of the American Fisheries Society. 120, 535-537. 44.Revilla, E., Palomares, F.,Delibes, M. (2000) Defining key habitats for low density populations of Eurasian badgers in Mediterranean environments. Biological Conservation . 95, 267-277. 45.Rogers, K. B., White, G.C. (2007) Analysis of movement and habitat use from telemetry data. American Fisheries Society. pp625-676. 46.Scruton, D.A. , Pennell, C.J. , Robertson, M.J. , Clarke, K.D. , Eddy, W. and McKinley, R.S. (2005) Telemetry studies of the passage route and entrainment of downstream migrating wild Atlantic salmon (Salmo salar) smolts at two hydroelectric installations on the Exploits River Newfoundland, Canada. Aquatic telemetry: advances and applications. Proceedings of the Fifth Conference on Fish Telemetry held in Europe. Ustica,Italy, 9-13. 47.Spedicato, M.T., Carbonara, P. ,Lembo, G. (2003) Insight into the homing behaviour of the dusky grouper (Epinephelus marginatus Lowe, 1834) around the island of Ustica, Italy. Aquatic telemetry: advances and applications. Proceedings of the Fifth Conference on Fish Telemetry held in Europe. Ustica,Italy, 9-13. 48.Stasko, A. B. , Pincock, D. G. (1977) Review of underwater biotelemetry with emphasis on ultrasonic techniques. Journal of the Fisheries Research Board of Canada.34, 1261-1285. 49.Tomkiewicz, S. M., Fuller, M. R., Kie, J. G. & Bates, K. K. (2010) Global positioning system and associated technologies in animal behaviour and ecological research. Phil. Trans. R. Soc. B. 365, 2221-2231. 50.Toni A. Beddow, Caroline Deary & Scott McKinley R. (1998) Migratory and reproductive activity of radio-tagged Arctic char (Salvelinus alpinus L.) in northern Labrador. Hydrobiologia. 371/372, 249–262. 51.Trefethen, P. S. (1956) Sonic equipment for tracking individual fish. Sonic equipment for tracking individual fish. Fisheries No. 179, Washington D.C 52.Turnpenny, A. W. H., Williams ,R. (1980) Effects of sedimentation on the gravels of an industrial river system. Journal of Fish Biology. 17,681-693. 53.Vehanen , T., Hyva¨rinen, P., Johansson, K. and Laaksonen, T. (2006) Patterns of movement of adult northern pike(Esox lucius L.) in a regulated river. Ecology of Freshwater Fish. 15,154-160. 54.Voegeli, F.A., McKinnon, G.P. (1995) Recent developments in ultrasonic tracking systems. Underwater Telemetry. Proceedings of the First Conference and Workshop on Fish Telemetry in Europe. (Baras, E. and J.C. Philipport, Eds.). Liege, Belgium. pp.235-241. 55.Winter, J.D. (1996) Advances in underwater biotelemetry. Fisheries Techniques, 2 nd Edition. American Fisheries Society, Bethesda,Maryland. Pp555-590. 56.Young, M. K. (1998) Inﬂuence of macroinvertebrate drift and light on activity and movement of Colorado river cutthroat trout. Transactions of the American Fisheries Society. 126, 428-437. 57.Yuya Makiguchi , Lin-Yan Liao ,Yoshifumi Konno , Hisaya Nii, Katsuya Nakao, Jin-Chywan Gwo, Hiroshi Onozato , Yii-Shing Huang ,Hiroshi Ueda. (2009) Site Fidelity of and Habitat Use by the Formosan Landlocked Salmon (Oncorhynchus masou formosanus) during Typhoon Season in Chichiawan Stream, Taiwan as Assessed by Nano-tag Radio Telemetry. Zoological Studies .48(4), 460-467. 58.大屯溪流域環境規劃設計， (2003)，私立中國文化大學環境設計學院景觀學研究所。 59.公共工程委員會，大屯溪整治工程，http://eem.pcc.gov.tw/?q=node/187 60.水量測定方法—量水堰法 (2005)，行政院環境保護署公告 61.王承龍，(2009)，應用克利金與逐步指標模擬分析魚類喜好流況之時空變異-以大屯溪日本禿頭鯊為例，臺灣大學碩士論文。 62.王漢泉，(2002)，台灣河川水質魚類指標之研究，環境檢驗所環境調查研究年報 9：207-236。 63.吳富春、鄭武慎，(1999)，以無線電量測系統探討池堰式魚道中臺灣石魚賓之溯泳行為，農業工程學報，第45卷第2期。 64.李宗祐，(2003)，氣候變遷對櫻花鉤吻鮭棲地水溫及族群數量之影響，臺灣大學生物環境系統工程研究所碩士論文。 65.汪靜明，(1990)，河川魚類棲地生態調查之基本原則與技術。 66.汪靜明，(2000)，大甲溪水資源環境教育，經濟部水資源局，30-45頁。 67.汪靜明，(2002)，台北縣大屯溪河川生態調查及溪流生態工法教育宣導計畫成果報告，中華民國生態資訊協會。 68.林弘都、蔡昆展、林宗鍵、王建平、蔣鎮宇，(2005)，台灣鏟頷魚的親緣地理及保育遺傳學，特有物研究保育中心-自然保育季刊。 69.林裕彬，(2004)，快速生物評估方法應用之可行性分析-以大屯溪為例，農工研討會。 70.武為瑤，(2011)，應用遺傳規劃法與二維水理模式評估河川魚類棲地-以大屯溪日本禿頭鯊為例，臺灣大學碩士論文。 71.張明雄、林曜松，(1998)，防砂壩對水生生物多樣性的影響、生物多樣性研討會論文集。 72.張德鑫，(2007)，蒸發散量 Penman-Monteith 估算方程式最適蒸汽壓力差計算式之評估，中原大學碩士學位論文。 73.陳昶憲、鐘侑達、方維鈞，(2005)，遺傳規劃法在河川演算之應用，台灣水利季刊，第53卷，第4期。 74.陳義雄、方力行，(1999)，台灣淡水及河口魚類誌。 75.童慶斌，(2008)，啟發式演算法課程講義，臺灣大學生物環境系統工程研究所。 76.楊奕岑，(2005)，遺傳規劃模式 3.0版及使用手冊。 77.經濟部水利署-網際水利地理資訊系統http://gmap.wra.gov.tw/wrahub_3wgis/ 78.葉明峰，(2005)，魚類河川棲地適合度調查技術，特有生物研究保育中心-農政與農情第155期。
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/66242	-
dc.description.abstract	溪流魚類棲息於不同環境條件及季節下，將反應其活動性變化與棲地喜好，其中以河川內水溫、流量影響最為顯著，將可改變魚類之生殖環境與活動行為。其中，魚類於生殖季節為使生理機能正常運作，需要在低水溫環境下進行生殖行為，故須考量其溫度容忍範圍。此外，過低之溪流量造成河川棲地不連續性，使魚類無法溯泳而上進行繁衍；颱風及豪雨後之高流量亦會造成上游棲地結構破壞，將魚類迅速沖至下游高水溫流域，最後使魚類受到下游攔河堰之阻隔而無法回到上游棲地，上述環境因子可造成魚類族群縮小與區隔化、洄游受阻等影響。本研究利用無線電遙測技術，追蹤台灣鏟頷魚棲息於攔河堰之下游及上游河段之日間活動行為，藉此取代過去間歇性調查方式。利用訊號變異反應台灣鏟頷魚在不同時期內之行為策略、活動範圍與活動力，並將資料利用遺傳規劃法及迴歸分析建立魚類活動性與水溫、流量之關係方程式，探討台灣鏟頷魚其日間活動性與流量、水溫變數之關係，進一步推測魚類生態行為與河川棲地之相關特性。研究結果顯示，應用遺傳規劃法建立魚體活動性與流量、水溫變數之關係式中，水溫變數分析魚體活動性時之判定係數為 0.50，流量則為 0.47，而同時考量水溫及流量變數之判定係數能達到 0.76，且關係式之趨勢指出台灣鏟頷魚在水溫上昇時，其活動性將提高，每日以中午時段之活動性最高。而短期內微幅流量變化對台灣鏟頷魚活動性之影響不如水溫敏感，但流量明顯變化時，將提高魚體活動性。此外，攔河堰上游之魚體活動性與水溫、流量之間，比下游魚體具有更高相關性。整體而言，仍以水溫變化為影響魚體活動性之主要因素。本研究過程中之台灣鏟頷魚皆呈現強烈上溯特性，且活動性受到攔河堰之影響顯著，此亦說明河川工程會對魚類行為產生干擾，應審慎考量工程規劃，做為未來進行棲復育與河川生態工程規劃之參考依據。	zh_TW
dc.description.abstract	Freshwater fish respond to seasonal variation in environmental conditions by altering patterns of activity and habitat selection, especially stream flow and water temperature. These environment variable change fish’s reproductive behavior and fish activity. For instance, fish search for appropriate habitats for spawn, usually in low-temperature environment. Furthermore, low stream flow rate make fragmentation of their habitat. Typhoon and heavy rainfall will decrease upstream fish habitat and fish rushed to the high water temperature basin, finally, the fish cumulated below the impassible weir, unable to return to the upstream habitat. To sum up, these environmental factors can decrease fish populations, segmentation and blocked fish migration. In this study, used radio-telemetry technology to investigate the diurnal fish activity of adult Varicorhinus barbatulus around a stream weir, we replaced the intermittent method of investigation. The use of signal strength variation as a measure of fish activity, differences in patterns of fish activity have significant implications for fish behavior strategy, home range and activity. The genetic programming and regression analysis were used to model the stream temperature, flow rate variations and fish activity, then compare these environment variable about Varicorhinus barbatulus, speculated the Varicorhinus barbatulus’s ecological characteristic.In the result, genetic programming establish a relationship among fish activity, temperature and flow rate. Considered all these environment variable, the result show that the coefficient of determination of water temperature was higher than stream flow rate, point out that fish activity will rise in high temperature, and the significant peak was during daylight around noon. The fish activity is sensitive to stream water	en
dc.description.provenance	Made available in DSpace on 2021-06-17T00:26:57Z (GMT). No. of bitstreams: 1 ntu-101-R98622038-1.pdf: 3665601 bytes, checksum: fdfd436869ecaab14c4f5214b83c5038 (MD5) Previous issue date: 2012	en
dc.description.tableofcontents	謝誌................. ................i 摘要.......................... .......ii Abstract ............................ iii 目錄 .................................. v 圖目錄 ...............................vii 表目錄 ................................ x 第一章緒論 .......................... 1 1-1 研究緣起........................... 1 1-2 研究目的 .......................... 3 1-3 研究流程圖 ........................ 4 第二章文獻回顧 ...................... 5 2-1 無線電遙測追蹤於魚類活動之應用 .... 5 2-2 無線電遙測技術於魚類活動性之應用 .. 8 2-3 實驗魚類-台灣鏟頷魚 .............. 11 2-4 魚體麻醉標誌 ..................... 13 第三章理論與方法 ................... 14 3-1 研究區域 ........................ 14 3-1-1 大屯溪流域 ..................... 14 3-1-2 追蹤河段之選擇 ................. 17 3-1-3 河段物理棲地因子調查 ........... 18 3-2 魚體捕捉、麻醉鎮靜及標誌 ........ 21 3-3 無線電追蹤儀器 ................... 24 3-4 無線電追蹤 ....................... 27 3-5 遺傳規劃法 ....................... 29 3-6 地理資訊系統 ..................... 35 第四章結果與討論 ................... 36 4-1 台灣鏟頷魚之棲地利用 ............ 36 4-2 魚類標誌與放流棲地狀態 .......... 45 4-3 台灣鏟頷魚之日間活動性變化 ...... 51 4-4 迴歸分析結果 .................... 70 4-5 遺傳規劃法之模擬結果 ............ 78 第五章結論與建議 ................... 85 5-1 結論 ............................ 85 5-2 建議 ............................ 90 參考文獻 ............................. 91 附錄一遺傳規劃模式3.0 使用手冊...... 97
dc.language.iso	zh-TW
dc.subject	遺傳規劃法	zh_TW
dc.subject	無線電遙測	zh_TW
dc.subject	魚類活動性	zh_TW
dc.subject	台灣鏟頷魚	zh_TW
dc.subject	水溫	zh_TW
dc.subject	流&#63870	zh_TW
dc.subject	無線電遙測	zh_TW
dc.subject	魚類活動性	zh_TW
dc.subject	台灣鏟頷魚	zh_TW
dc.subject	遺傳規劃法	zh_TW
dc.subject	水溫	zh_TW
dc.subject	流&#63870	zh_TW
dc.subject	genetic programming	en
dc.subject	radio telemetry	en
dc.subject	stream flow	en
dc.subject	water temperature	en
dc.subject	stream flow	en
dc.subject	fish activity	en
dc.subject	Varicorhinus barbatulus	en
dc.subject	water temperature	en
dc.subject	radio telemetry	en
dc.subject	fish activity	en
dc.subject	Varicorhinus barbatulus	en
dc.subject	genetic programming	en
dc.title	應用無線電遙測技術及遺傳規劃法探討大屯溪台灣鏟頷魚日間活動性與流量水溫之關係	zh_TW
dc.title	Application of radio telemetry and genetic programming to study the relationship among diurnal fish activity, water temperatures and streamflow : A case of Varicorhinus barbatulus in Datuan stream	en
dc.type	Thesis
dc.date.schoolyear	100-1
dc.description.degree	碩士
dc.contributor.oralexamcommittee	童慶斌(Ching-pin Tung),任秀慧(Sau-wai Yam)
dc.subject.keyword	無線電遙測,魚類活動性,台灣鏟頷魚,遺傳規劃法,水溫,流&#63870,	zh_TW
dc.subject.keyword	radio telemetry,fish activity,Varicorhinus barbatulus,genetic programming,water temperature,stream flow,	en
dc.relation.page	103
dc.rights.note	有償授權
dc.date.accepted	2012-02-15
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	生物環境系統工程學研究所	zh_TW
顯示於系所單位：	生物環境系統工程學系

文件中的檔案：

檔案	大小	格式
ntu-101-1.pdf 未授權公開取用	3.58 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。