請用此 Handle URI 來引用此文件:
http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/64397
完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 孫志陸 | |
dc.contributor.author | Chen-Te Tseng | en |
dc.contributor.author | 曾振德 | zh_TW |
dc.date.accessioned | 2021-06-16T17:44:51Z | - |
dc.date.available | 2012-08-22 | |
dc.date.copyright | 2012-08-22 | |
dc.date.issued | 2012 | |
dc.date.submitted | 2012-08-14 | |
dc.identifier.citation | References
Andrade, H.A., Garcia, C.A.E. (1999) Skipjack tuna fishery in relation to sea surface temperature off the southern Brazilian coast. Fisheries Oceanography, 8(4): 245–254. Attrill, M.J., Power, M. (2002) Climatic influence on a marine fish assemblage. Nature, 417: 275–278. Bakun, A., (2006) Fronts and eddies as key structures in the habitat of marine fish larvae: opportunity, adaptive response and competitive advantage. Scientia Marina, 70: 105–122. Batten, S., Chen, X., Flint, E.N., Freeland, H.J., Holmes, J., Howell, E., Ichii, T., Kaeriyama, M., Landry, M., Lunsford, C., Mackas, D.L., Mate, B., Matsuda, K., McKinnell, S.M., Miller, L., Morgan, K., Pena, A., Polovina, J.J., Robert, M., Seki, M.P., Sydeman, W.J., Thompson, S.A., Whitney, F.A., Woodworth, P., Yamaguchi, A. (2010) Status and trends of the North Pacific oceanic region, 2003-2008, pp. 56-105 In S.M. McKinnell and M.J. Dagg. [Eds.] Marine Ecosystems of the North Pacific Ocean, 2003-2008. PICES Special Publication 4, 393 pp. Belkin, I.M., O’Reilly, J.E. (2009) An algorithm for oceanic front detection in chlorophyll and SST satellite imagery. Journal of Marine Systems, 78(3): 319–326. Behrenfeld, M.J., Falkowski, P.G. (1997) Photosynthetic rates derived from satellite-based chlorophyll concentration. Limnology and Oceanography. 42: 1–20. Behrenfeld, M.J, O’Malley, R.T., Siegel, D.A., McClain, C.R., Sarmiento, J.L., Feldman, G.C., Milligan, A.J., Falkowski, P.G., Letelier, R.M., Boss, E.S. (2006) Climate-driven trends in contemporary ocean productivity. Nature, 444: 752–755. Bograd, S.J., Foley, D.G., Schwing, F.B., Wilson, C., Laurs, R.M., Polovina, J.J., Howell, E.A., Brainard, R.E. (2004) On the seasonal and interannual migrations of the transition zone chlorophyll front. Geophysical Research Letters, 31, L17204, doi:10.1029/2004GL020637. Brander, K. (2009) Impacts of climate change on marine ecosystems and fisheries. Journal of the Marine Biological Association of India, 51(1): 1–13. Brevoort, J.C. (1856) Notes on some figures of Japanese fish taken from recent specimens by the artists of the U. S. Japan Expedition. Washington :s.n., 256pp. Brodeur, R.D. (1988) Zoogeography and trophic ecology of the dominant epipelagic fishes in the northern North Pacific. Bulletin of the Ocean Research Institute University of Tokyo, 26 (II): 1–27. Cayula, J.F., Cornillon, P. (1992) Edge detection algorithm for SST images. Journal of Atmospheric and Oceanic Technology, 9: 67–80. Chen, S. (2008) The Kuroshio Extension front from satellite sea surface temperature measurements. Journal of Oceanography, 64: 891–897. Chiswell, S.M. (1994) Variability in sea surface temperature around New Zealand from AVHRR Images. Zealand Journal of Marine and Freshwater New Research, 28: 179–192. Choudhury, S.B., Jena, B., Rao, M.V., Rao, K.H., Somvanshi, V.S., Gulati, D.K., Sahu, S.K. (2007) Validation of integrated potential fishing zone (IPFZ) forecast using satellite based chlorophyll and sea surface temperature along the east coast of India. International Journal of Remote Sensing, 28: 2683–2693. Ciannelli, L., Fauchald, P., Chan, K.S., Agostini, V.N., Dingsor, G.E. (2008) Spatial fisheries ecology: recent progress and future prospects. Journal of Marine Systems, 71: 223–236. Collins English Dictionary (2012) Saury. (n.d.). Collins English Dictionary-Complete & Unabridged 10th Edition. Retrieved March 09, 2012, from Dictionary.com website: http://dictionary.reference.com/browse/saury/. Cornillon, P., Watts, D.R. (1987) Satellite thermal infrared and inverted echo sounder determinations of the Gulf Stream northern edge. Journal of Atmospheric and Oceanic Technology, 4: 712–723. Damalas, D., Megalofonou, P., Apostolopoulou, M. (2007) Environmental, spatial, temporal and operational effects on swordfish (Xiphias gladius) catch rates of eastern Mediterranean Sea longline fisheries. Fisheries Research, 84: 233–246. Diehl, S.F., Budd, J.W., Ullman, D., Cayula, J.F. (2002) Geographic window sizes applied to remote sensing sea surface temperature front detection. Journal of Atmospheric and Oceanic Technology, 19: 1115–1113. Dormann, C.F., McPherson, J.M., Araújo, M.B., Bivand, R., Bolliger, J., Carl, G., Davies, R.G. (2007) Methods to account for spatial autocorrelation in the analysis of species distributional data: a review. Ecography, 30: 609–628. ESRI (2011) The literatures of ArcGIS 10.0 Desktop software. (http://www.esri.com). Eschmeyer, W.N., Herald, E.S., Hammann, H. (1983) A field guide to Pacific coast fishes of North America. Houghton Mifflin Company, U.S.A. 336pp. Eslinger, D.L., O'Brien, J.J., Iverson, R.L. (1989) Empirical orthogonal function analysis of cloud-containing Coastal Zone Color Scanner images of northeasterm North American coastal waters. Journal of Geophysical Research, 94: 10884–10890. EUR-OCEANS (2008) Adaptive management in pelagic fisheries. Fact Sheet 9., in: European Network of Excellence for Ocean Ecosystem Analysis (EUR-OCEANS) K.T.U. (Ed.). Paris, 2pp. Everson, R., Cornillon, P., Sirovich, L., Webber, A. (1997) An empirical eigenfunction analysis of sea surface temperature in the western North Atlantic. Journal of Physical Oceanography, 27: 468–479. FAO (1994) World review of highly migratory species and straddling stocks. FAO Fisheries Technical Papers, No. 337. Rome, FAO. 70pp. Fang, W., Hsieh, W.W. (1993) Summer sea surface temperature variability off Vancouver Island from satellite data. Journal of Geophysical Research, 98: 14391–14405. Fiedler, P.C., Bernard, H.J. (1987) Tuna aggregation and feeding near fronts observed in satellite imagery. Continental Shelf Research, 7: 871–881. Forget, M.-H., Stuart, V., Platt, T. (2009) Remote sensing in fisheries and aquaculture. Reports and Monographs of the International Ocean-Colour Coordinating Group, 8: 43–102. Fortier, L., Levasseur, M.E., Drolet, R., Therriault, J.C. (1992) Export production and the distribution of fish larvae and their prey in a coastal jet region. Marine Ecology Progress Series, 85: 203–218. Fotheringham, A.S., Brunsdon, C., Charlton, M. (1998) Geographically weighted regression: a natural evolution of the expansion method for spatial data analysis. Environment and Planning A, 30(11): 1905–1927. Fotheringham, A.S., Brunsdon, C., Charlton, M. (2002) Geographically Weighted Regression: the Analysis of Spatially Varying Relationships. John Wiley & Sons Ltd., England, 269pp. Froese, R., Pauly, D. (2012) FishBase. World Wide Web electronic publication. www.fishbase.org, version (02/2012). Fukushima, S., Watanabe, Y., Ogawa, Y. (1990) Correspondence of spawned seasons to large, medium, and small size Pacific saury exploited in the northwestern Pacific Ocean. Bulletin of Tohoku National Fisheries Research Institute, 52: 17–27 (in Japanese with English abstract). Gallaudet, T.C., Simpson, J.J. (1994) An empirical orthogonal function analysis of remotely sensed sea surface temperature variability and it's relation to interior oceanic processes off Baja California. Remote Sensing of Environment, 47: 375–389. Hal, R.V., Smits, K., Rijnsdorp, A.D. (2010) How climate warming impacts the distribution and abundance of two small flatfish species in the North Sea. Journal of Sea Research, 64: 76–84. Harrison, P.J., Parsons, T.R. (2000) Fisheries oceanography: An integrative approach to fisheries ecology and management. Blackwell Science Ltd, 360pp. Hastie, T.J., Tibshirani, R.J. (1990) Generalized additive models. London: Chapman and Hall, 352pp. Hazin, H., Erzini, K. (2008) Assessing swordfish distribution in the South Atlantic from spatial predictions. Fisheries Research, 90: 45–55. Hobday, A.J., Hartmann, K. (2006) Near real-time spatial management based on habitat predictions for a longline bycatch species. Fisheries Management and Ecology, 13: 365–380. Holyer, R.J., Peckinpaugh, S.H. (1989) Edge detection applied to satellite imagery of the oceans. IEEE Transactions on Geoscience and Remote Sensing, 27: 46–56. Hoshino, E., Milner-Gullandb, E.J., Hillary, R.M. (2012) Bioeconomic adaptive management procedures for short-lived species: A case study of Pacific saury (Cololabis saira) and Japanese common squid (Todarodes pacificus). Fisheries Research, 121–122: 17–30. Huang, W.B. (2007) Body Length, Weight, and Condition Factor of Pacific Saury (Cololabis saira) from the Landed Size-classes of Taiwanese Catch in Comparison with Japanese Statistics. Journal of the Fisheries Society of Taiwan, 34(4): 361–368. Huang, W.B. (2010) Comparisons of monthly and geographical variations in abundance and size composition of Pacific saury between the high-seas and coastal fishing grounds in the northwestern Pacific. Fisheries Science, 76(1): 21–31. Hubbs, C.L., Wisner, R.L. (1980) Revision of the sauries (Pisces, Scomberesoeidae) with description of two new genera and one new species. Fishery Bulletin US, 77: 521–566. Humphries, N.E., Queiroz, N., Dyer, J.R.M., Pade, N.G., Musyl, M.K., Schaefer, K.M., Fuller, D.W., Brunnschweiler, J.M., Doyle, T.K., Houghten, J.D.R., Hays, G.C., Jones, C.S., Noble, L.R., Wearmouth, V.J., Southall, E.J., Sims, D.W. (2010) Environmental contest explains Lévy and Brownian movement patterns of marine predators. Nature, 465: 1066–1069. IPCC (2007) Summary for Policymakers. In: Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change [Solomon, S., D. Qin, M. Manning, Z. Chen, M. Marquis, K.B. Averyt, M. Tignor and H.L. Miller (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA. Ito, S., Sugisaki, H., Tsuda, A., Yamamura, O., Okuda, K. (2004a) Contributions of the VENFISH program: meso-zooplankton, Pacific saury (Cololabis saira) and walleye pollock (Theragra chalcogramma) in the northwestern Pacific. Fisheries Oceanography, 13(Supplement 1): 1–9. Ito, S., Kishi, M.J., Kurita, K., Oozeki, Y., Yamanaka, T., Megrey, B.A., Werner, F.E. (2004b) Initial design for a fish bioenergetics model of Pacific saury coupled to a lower trophic ecosystem model. Fisheries Oceanography, 13(Supplement 1): 111–124. Iwahashi, M., Isoda, Y., Ito, S., Oozeki, Y., Suyama, S. (2006) Estimation of seasonal spawning ground locations and ambient sea surface temperatures for eggs and larvae of Pacific saury (Cololabis saira) in the western North Pacific. Fisheries Oceanography, 15(2): 125–138. Jensen, O.P., Ortega-Garcia, S., Martell, S.J.D., Ahrens, R.N.M., Domeier, M.L., Walters, C.J., Kitchell, J.F. (2010) Local management of a' highly migratory species': The effects of long-line closures and recreational catch-and-release for Baja California striped marlin fisheries. Progress in Oceanography, 86(1–2): 176–186. Kawamara, R. (1994) A rotated EOF analysis of global surface temperature variability with interannual and interdecadal scales. Journal of Physical Oceanography, 24: 709–715. Kelly, K.A. (1985) The influence of winds and topography on the sea surface temperature patterns over the northern California slope. Journal of Geophysical Research, 90: 11783–11798. Kosaka, S. (2000) Life history of Pacific saury Cololabis saira in the Northwest Pacific and consideration of resource fluctuation based on it. Bulletin of Tohoku National Fisheries Research Institute, 63: 1–96 (in Japanese with English abstract). Krivoruchko, K. (2011) Spatial statistical data analysis for GIS users. E-book, ESRI Press, California, 928pp. Kurita, Y. (2003) Energetics of reproduction and spawning migration for Pacific saury (Cololabis saira). Fish Physiology and Biochemistry, 28: 271–272. Kurita, Y., Nemoto, Y., Oozeki, Y., Hayashizaki, K.I., Ida, H. (2004) Variations in patterns of daily changes in otolith increment widths of 0+ Pacific saury, Cololabis saira, off Japan by hatch date in relation to the northward feeding migration during spring and summer. Fisheries Oceanography, 13(Supplement 1): 54–62. Kurita, Y. (2006) Regional and interannual variations in spawning activity of Pacific saury Cololabis saira during northward migration in spring in the north-western Pacific. Journal of Fish Biology, 69: 846–859. Kuwahara, H., Akeda, S., Kobayashi, S., Takeshita, A., Yamashita, Y., Kido, K. (2006) Predicted changes on the distribution areas of marine organisms around Japan casued by the global warming. Global Environmental Research, 10(2): 189–199. Laevastu, T., Hayes, M.L. (1981) Fisheries oceanography and ecology. Fishing News Books: Farnham. XIV, 199pp. Lagerloef, G.S.E., Bernstein, R.L. (1988) Empirical orthogonal function analysis of Advanced Very High Resolution Radiometer surface temperature pattern in Santa Barbara Channel. Journal of Geophysical Research, 93: 6863–6873. Laurs, R.M., Fiedler, P.C., Montgomery, D.R. (1984) Albacore tuna catch distributions relative to environmental features observed from satellites. Deep Sea Research, 31: 1085–1099. Lehodey, P., Bertignac, M., Hampton, J., Lewis, A., Picaut, J. (1997) El Niño Southern Oscillation and tuna in the western Pacific. Nature, 389: 715–718. Lehodey, P., Andre, J.M., Bertignac, M., Hampton, J., Stones, A., Menkes, C., Memery, L., Grima, N. (1998) Predicting skipjack tuna forage distributions in the equatorial Pacific using a coupled dynamical bio-geochemical model. Fisheries Oceanography, 7: 317–325. Mitani, Y., Bando, T., Takai, N., Sakamoto, W. (2006) Patterns of stable carbon and nitrogen isotopes in the baleen of common minke whale Balaenoptera acutorostrata from the western North Pacific. Fisheries Science, 72: 69–76. Mueter, F.J., Broms, C., Drinkwater, K.F., Friedland, K.D., Hare, J.A., Hunt, Jr.G.L., Melle, W. (2009) Ecosystem responses to recent oceanographic variability in high-latitude Northern Hemisphere ecosystems. Progress in Oceanography, 81: 93–110. Mukai, D., Kishib, M.J., Ito, S., Kurita, Y. (2007) The importance of spawning season on the growth of Pacific saury: A model-based study using NEMURO.FISH. Ecological Modeling, 202: 165–173. Munk, P., Fox, C.J., Bolle, L.J., Damme, C.J.G., Fossum, P., Kraus, G. (2009) Spawning of North Sea fishes linked to hydrographic features. Fisheries Oceanography, 18(6): 458–469. Nakamura, H., Ichikawa, H., Nishina, A. Lie, H.J. (2003) Kuroshio path meander between the continental slope and the Tokara Strait in the East China Sea. Journal of Geophysical Research, 108: 3360, doi:10.1029/2002JC001450. Nitani, H. (1972) Beginning of the Kuroshio. In Kuroshio: Its physical aspects. ed. by H. Stommel and K. Yoshida, Univ. of Tokyo Press, Tokyo: 129–163. Ocean Color Web (2011) http://oceancolor.gsfc.nasa.gov/. Odate (1994) Zooplankton biomass and its long-term variation in the western North Pacific Ocean, Tohoku sea area, Japan. Bulletin of Tohoku National Fisheries Research Institute, 56: 115–173 (in Japanese with English abstract). OFDC (2010) Catch statistics of squid jigging fishery. Overseas Fisheries Development Council of the Republic of China (OFDC). http://www.ofdc.org.tw/. Olson, D.B. (2011) Biophysical dynamics of western transition zones: a preliminary synthesis. Fisheries Oceanography, 10(2): 133–150. Oozeki, Y., Watanabe, Y., Kurita, Y., Nakata, K., Kitagawa, D. (2003) Growth rate variability of Pacific saury, Cololabis saira, larvae in the Kuroshio waters. Fisheries Oceanography, 12(4/5): 419–424. Oozeki, Y., Watanabe, Y., Kitagawa, D. (2004) Environmental factors affecting larval growth of Pacific saury, Cololabis saira, in the northwestern Pacific Ocean. Fisheries Oceanography, 13: 44–53. Palacios, D.M., Bograd, S.J., Foley, D.G., Schwing, F.B. (2006) Oceanographic characteristics of biological hot spots in the North Pacific: A remote sensing perspective. Deep-Sea Research II, 53: 250–269. Polovina, J.J., Howell, E.A. (2005) Ecosystem indicators derived from satellite remotely sensed oceanographic data for the North Pacific. ICES Journal of Marine Science, 62: 319–327. Polovina, J.J., Howell, E.A., Kobayashi, D.R., Seki, M.P. (2001) The transition zone chlorophyll front, a dynamic global feature defining migration and forage habitat for marine resources. Progress in Oceanography, 49: 469–483. Qiu, B. (2001) Kuroshio and Oyashio Current. In: Steele J.H., Turekian K.K., Thorpe S.A. (eds) Encyclopedia of ocean science. Academic Press, New York: 1413–1425. Rajapaksha, J.K., Nishida, T., Samarakoon, L. (2010) Environmental preferences of yellowin tuna (Thunnus albacores) in the northeast Indian Ocean: an application of remote sensing data to longline catches. IOTC-2010-WPTT-43: 1–16. R Development Core Team (2012) R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. http://www.R-project.org. Roberts, J.J., Best, B.D., Dunn, D.C., Treml, E.A., Halpin, P.N. (2010) Marine Geospatial Ecology Tools: An integrated framework for ecological geoprocessing with ArcGIS, Python, R, MATLAB, and C++. Environmental Modelling & Software, 25: 1197–1207. Robinson, I.S. (2004) Measuring the Oceans from Space: The principles and methods of satellite oceanography. Springer Praxis Books, 714pp. Roden, G.I. (1991) Subarctic-subtropical transition zone of the North Pacific: Large-scale aspects and mesoscale structure. In: Wetherall JA (ed) Biology, oceanography, and fisheries of the North Pacific transition zone and subarctic frontal zone. NOAA Technical Report NMFS, 105: 1–38 Sablin, V.V., Pavlychev, V.P. (1982) Dependence of migration and catch of Pacific saury upon thermal conditions. Bulletin of Tohoku National Fisheries Research Institute, 44: 109–117 (in Japanese with English abstract). Saitoh, S.I., Kosaka, S., Lisaka, J. (1986) Satellite infrared observations of Kuroshio warm-core rings and their application to study of Pacific saury migration. Deep-Sea Research, 33: 1601–1615. Sakurai, Y. (2007) An overview of the Oyashio ecosystem. Deep-Sea Research II, 54: 2526–2542. Sassa, C., Kawaguchi, K., Taki, K. (2007) Larval mesopelagic fish assemblages in the Kuroshio-Oyashio transition region of the western North Pacific. Marine Biology, 150: 1403–1415. Schick, R.S., Goldstein, J., Lutcavage, M.E. (2004) Bluefin tuna (Thunnus thynnus) distribution in relation to sea surface temperature fronts in the Gulf of Maine (1994–96). Fisheries Oceanography, 13(4): 225–238. Schwing, F.B., Mendelssohn, R., Bograd, S.J., Overland, J.E., Wang, M., Ito, S. (2010) Climate change, teleconnection patterns, and regional processes forcing marine populations in the Pacific. Journal of Marine Systems, 79: 245–257. Shimizu, Y., Takahashi, K., Ito, S.I., Kakehi, S., Tatebe, H., Yasuda, I., Kusaka, A., Nakayama, T. (2009) Transport of subarctic large copepods from the Oyashio area to the mixed water region by the coastal Oyashio intrusion. Fisheries Oceanography, 18(5): 312–327. Solanki, H.U., Dwivedi, R.M., Navak, S.R., Somvanshi, V.S., Gulati, D.K., Panttnavak, S.K. (2003) Fishery forecast using OCM chlorophyll concentration and AVHRR SST: validation results off Gujarat coast, India. International Journal of Remote Sensing, 24: 3691–3699. Solanki, H.U., Mankodi, P.C., Navak, S.R., Somvanshi, V.S. (2005) Evaluation of remote-sensing-based potential fishing zones (PFZs) forecast methodology. Continental Shelf Research, 25: 2163–2173. Solanki, H.U., Mankodi, P.C., Dwivedi, R.M., Nayak, S.R. (2008) Satellite observations of main oceanographic processes to identify ecological associations in the Northern Arabian Sea for fishery resources exploration. Hydrobiologia, 612: 269–279. Springer, A.M., Piatt, J.F., Shuntov, V.P., Van Vliet, G.B., Vladimirov, V.L., Kuzin, A.E., Perlov, A.S. (1999) Marine birds and mammals of the Pacific Subarctic Gyres. Progress in Oceanography, 43: 443-487. Stenevik, E.K., Sundby, S. (2007) Impacts of climate change on commercial fish stocks in Norwegian waters. Marine Policy, 31: 19–31. Stommel, H., Yoshida, K. (1972) Kuroshio: Its Physical Aspects. University of Tokyo Press, 517pp. Su, N.J., Yeh, S.Z., Sun, C.L., Punt, A.E., Chen, Y., Wang, S.P. (2008) Standardizing catch and effort data of the Taiwanese distant-water longline fishery in the western and central Pacific Ocean for bigeye tuna, Thunnus obesus. Fisheries Research, 90(1–3): 235–246. Su, N.J., Sun, C.L., Punt, A.E., Yeh, S.Z., DiNardo, G. (2011) Evaluation of a spatially sex-specific assessment method incorporating a habitat preference model for blue marlin (Makaira nigricans) in the Pacific Ocean. Fisheries Oceanography, 20(5): 415–433. Sugisaki, H., Kurita, Y. (2004) Daily rhythm and seasonal variation of feeding habit of Pacific saury (Cololabis saira) in relation to their migration and oceanographic conditions off Japan. Fisheries Oceanography, 13(Supplement 1): 63–73. Sugisaki, H., Nonaka, M., Ishizaki, S., Hidaka, K., Kameda, T., Hirota, Y., Oozeki, Y., Kubota, H., Takasuka, A. (2010) Status and trends of the Kuroshio Current region, 2003-2008, pp 330-359 In, S.M. McKinnell and M.J. Dagg [Eds.] Marine Ecosystems of the North Pacific Ocean, 2003-2008. PICES Special Publication 4, 393pp. Suyama, S., Sakurai, Y., Shimazaki, K. (1996) Age and Growth of Pacific Saury Cololabis saira (Brevoort) in the Western North Pacific Ocean Estimated from Daily Otolith Growth Incrementsts. Fisheries Science, 62(1): 1–7. Suyama, S., Oshima, K., Nakagami, M., Ueno, Y. (2009) Seasonal change in the relationship between otolith radius and body length in age-zero Pacific saury Cololabis saira. Fisheries Science, 75: 325–333. Suyama, S., Oshima, K., Nakagami, M., Kawabata, A. (2011) Seasonal changes in otolith and somatic growth in age-0 Pacific saury Cololabis saira. Fisheries Science, 77: 223–233. Taguchi, S., Saito, H., Kasai, H., Kono, T., Kawasaki, Y. (1992) Hydrography and spatial variability in the size distribution of phytoplankton along the Kurile Islands in the western subarctic Pacific Ocean. Fisheries Oceanography, 1: 227–237. Taki, K. (2008) Vertical distribution and diel migration of euphausiids from Oyashio Current to Kuroshio area off northeastern Japan. Plankton & Benthos Research, 3(1): 27–35. Taki, K. (2011) Distribution and population structure of Thysanoessa inspinata and its dominance among euphausiids off northeastern Japan. Journal of Plankton Research, 33(6): 891–906. Tamura, T., Fujise, Y. (2002) Geographical and seasonal changes of the prey species of minke whale in the Northwestern Pacific. ICES Journal of Marine Science, 59: 516–528. Teo, S.L.H., Boustany, A.M., Block, B.A. (2007) Oceanographic preferences of Atlantic bluefin tuna, Thunnus thynnus, on their Gulf of Mexico breeding grounds. Marine Biology, 152: 1105–1119. Tian, Y., Akamine, T., Suda, M. (2003) Variations in the abundance of Pacific saury (Cololabis saira) from the northwestern Pacific in relation to oceanic-climate changes. Fisheries Research, 60: 439–454. Tian, Y., Ueno, Y., Suda, M., Akamine, T. (2004) Decadal variability in the abundance of Pacific saury and its response to climatic/oceanic regime shifts in the northwestern subtropical Pacific during the last half century. Journal of Marine Systems, 52(1–4): 235–257. Tian, S., Chen, X., Chen, Y., Xu, L., Dai, X. (2009) Standardizing CPUE of Ommastrephes bartramii for Chinese squid-jigging fishery in Northwest Pacific Ocean. Chinese Journal of Oceanology and Limnology, 27: 729–739. Tittensor, D.P., Mora, C., Jetz, W., Lotze, H.K., Ricard, D., Berghe, E.V., Worm, B. (2010) Global patterns and predictors of marine biodiversity across taxa. Nature, 466: 1098–1011. Tohoku National Fisheries Research Institute (2010) Stock assessment report of Pacific saury in the north western Pacific. Fisheries Agency of Japan, Tokyo (in Japanese), 11pp. Tseng, C.T., Lin, C.Y., Chen, S.C., Shyu, C.Z. (2000) Temporal and spatial variations of sea surface temperature in the East China Sea. Continental Shelf Research, 20: 373–387. Tseng, C.T., Sun, C.L., Yeh, S.Z., Chen, S.C., Su, W.C. (2010) Spatio-temporal distributions of tuna species and potential habitats in the Western and Central Pacific Ocean derived from multi-satellite data. International Journal of Remote Sensing, 31(17&18): 4543–4558. Tseng, C.T., Sun, C.L., Yeh, S.Z., Chen, S.C., Su, W.C., Liu, D.C. (2011) Influence of climate-driven sea surface temperature increase on potential habitats of the Pacific saury (Cololabis saira). ICES Journal of Marine Science, 68(6): 1105–1113. Tseng, C.T., Sun, C.L., Yeh, S.Z., Chen, S.C., Liu, D.C., Su, W.C. (2011) The Kuroshio variations from satellite-derived sea surface temperature and Argos satellite-tracking Lagrangian drifters. International Journal of Remote Sensing, 32(23): 8725–8746. Tserpes, G., Peristeraki, P., Valavanis, V.D. (2008) Distribution of swordfish in the eastern Mediterranean, in relation to environmental factors and the species biology. Hydrobiologia, 612: 241–250. Ullman, D.S., Cornillon, P.C. (2000) Evaluation of front detection methods for satellite-derived SST data using in situ observations. Journal of Atmospheric and Oceanic Technology, 17(12): 1667–1675. Vázquez, D.P., Atae-Allah C., Luque-Escamilla, P.L. (1999) Entropic approach to edge detection for SST images. Journal of Atmospheric and Oceanic Technology, 16(7): 970–979. Venables, W.N., Dichmont, C.M. (2004) GLMs, GAMs and GLMMs: an overview of theory for applications in fisheries research. Fisheries Research, 70: 319–337. Wall,C.C., Muller-Karger, F.E., Roffer, M.A., Hu, C., Yao, W., Luther, M.E. (2008) Satellite remote sensing of surface oceanic fronts in coastal waters off west–central Florida. Remote Sensing of Environment, 112(6): 2963–2976. Walsh, W.A., Ito, R.Y., Kawamoto, K.E., McCracken, M. (2005) Analysis of logbook accuracy for blue marlin (Makaira nigricans) in the Hawaii-based longline fishery with a generalized additive model and commercial sales data. Fisheries Research, 75: 175–192. Watanabe, Y., Butler, J.L., Mori, T. (1988) Growth of Pacific saury, Cololabis saira, in the northeastern and northwestern Pacific ocean. Fishery Bulletin US, 86: 489–498. Watanabe, Y., Lo, N.C.H. (1989) Larval production and mortality of Pacific saury, Cololabis saira, in the northwestern Pacific Ocean. Fisheries Bulletin US, 78: 601–613. Watanabe, Y., Oozeki, Y., Kitagawa, D. (1997) Larval parameters determining preschooling juvenile production of Pacific saury (Cololabis saira) in the northwestern Pacific. Canadian Journal of Fisheries and Aquatic Sciences, 54: 1067–1076. Watanabe, Y., Kurita, Y., Noto, M., Oozeki, Y., Kitagawa, D. (2003) Growth and Survival of Pacific Saury Cololabis saira in the Kuroshio-Oyashio Transitional Waters. Journal of Oceanography, 59: 403–414. Watanabe, K., Tanaka, E., Yamada, S., Kitakado, T. (2006) Spatial and temporal migration modeling for stock of Pacific saury Cololabis saira (Brevoort), incorporating effect of sea surface temperature. Fisheries Science, 72(6): 1153–1165. Watanabe, Y. (2007) Latitudinal variation in the recruitment dynamics of small pelagic fishes in the western North Pacific. Journal of Sea Research, 58(1): 46–58. Watanabe, Y. (2009) Recruitment variability of small pelagic fish populations in the Kuroshio-Oyashio transition region of the Western North Pacific. Journal of Northwest Atlantic Fishery Science, 41: 197–204. Weare, B.C., Navato, A.R., Newell, R.E. (1976) Empirical orthogonal analysis of Pacific sea surface temperatures. Journal of Physical Oceanography, 6: 671–678. Windle, M.J., Rose, G.A., Devillers, R., Fortin, M.J. (2009) Exploring spatial non-stationary of fisheries survey data using geographically weighted regression (GWR): an example fromt the Northwest Atlantic. ICES Journal of Marine Science, 67: 145–154. Wright, D. (2011) GIS for the ocens. E-book, ESRI Press, California, 94pp. Yamamura, O. (1997) Scavenging on discarded saury by demersal fishes off Sendai Bay, northern Japan. Journal of Fish Biology, 50: 919–925. Yasuda, I., Okuda, K., Shimizu, Y. (1996) Distribution and modification of North Pacific Intermediate Water in the Kuroshio–Oyashio interfrontal zone. Journal of Physical Oceanography, 26: 448–465. Yasuda, I., Watanabe, T. (1994) On the relationship between the Oyashio front and saury fishing grounds in the northwestern Pacific: a forecasting method for fishing ground locations. Fisheries Oceanography, 3(3): 172–181. Yasuda, I., Watanabe, T. (2007) Chlorophyll a variation in the Kuroshio Extension revealed with a mixed-layer tracking float: implication on the long-term change of Pacific saury (Cololabis saira). Fisheries Oceanography, 16(5): 482–488. Yu, Y., Emery, W.J. (1996) Satellite derived sea surface temperature variability in the western Tropical Pacific Ocean, 1992}1993. Remote Sensing of Environment, 58: 299–310. Zainuddin, M., Saitoh, K., Saitoh, S.-I. (2004) Detection of potential fishing ground for albacore tuna using synoptic measurements of ocean color and thermal remote sensing in the northwestern North Pacific. Geophysical Research Letters, 31: 20311. Zainuddin, M., Kiyofuji, H., Saitoh, K., Saitoh, S. I. (2006) Using multi-sensor satellite remote sensing and catch data to detect ocean hot spots for albacore (Thunnus alalunga) in the northwestern North Pacific. Deep-Sea Research II, 53(3/4): 419–431. Zainuddin, M., Saitoh, K., Saitoh, S.I. (2008) Albacore (Thunnus alalunga) fishing ground in relation to oceanographic conditions in the western North Pacific Ocean using remotely sensed satellite data. Fisheries Oceanography, 17: 61–73. Zhang, C.I., Hollowed, A.B., Lee, J.B., Kim, D.H. (2011) An IFRAME approach for assessing impacts of climate change on fisheries. ICES Journal of Marine Science, 68: 1318–1328. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/64397 | - |
dc.description.abstract | 本論文處理分析2006–2010年多重衛星遙測影像(海面水溫、海洋水色及基礎生產力等),利用區域性及全域性空間分析模式,建立西北太平洋臺灣遠洋秋刀魚(Pacific saury, Cololabis Saira)漁獲分布與海洋環境因子之相關性。同時,也利用不同的影像處理及邊緣偵測技術,以及地理資訊系統之空間整合套疊與地理統計分析等方法,探討重要水文特徵(水溫鋒面及特定等值線等)對秋刀魚魚群分布及移動洄遊特性之影響,並推測秋刀魚之漁場分布。結果顯示,漁季初期(6至8月)平均單位努力漁獲量(catch per unit effort, CPUE)較低,其CPUE為10.8公噸/艘/日,盛漁期為9至11月,最高CPUE為10月份之23.1公噸/艘/日,總平均CPUE為15.3公噸/艘/日。臺灣遠洋秋刀魚作業漁場,主要分布於北緯37–48度、東經145–165度,其月別漁獲重心呈現明顯的緯度向變化,受亞熱帶環流鋒面及亞極區環流鋒面相互作用,主要漁場分布於黑潮(Kuroshio)及親潮(Oyashio)的交匯海域。另外,本論文亦利用Cayula–Cornillon直方圖邊緣偵測技術,處理分析衛星海面水溫影像,萃取出水溫鋒面(潮境)分布位置,藉以探討秋刀魚漁獲海域與水溫鋒面之相關性。結果顯示,6至8月份,作業海域內水溫鋒面較少,秋刀魚CPUE也偏低。相反地,9至11月份,水溫鋒面明顯增加,秋刀魚CPUE也隨著提高。同時也發現,秋刀魚的漁獲位置愈靠近水溫鋒面分布海域,其CPUE也比較高,CPUE與最近的水溫鋒面距離,呈現顯著負相關。
此外,本論文亦利用經驗累積分布函數(empirical cumulative distribution function),處理分析秋刀魚可能棲息海域(potential saury habitat)之海洋環境因子主要分布範圍。結果顯示,臺灣遠洋秋刀魚作業漁場內,魚群可能棲息海域之海面水溫值為14–16 oC,海洋水色值為0.4–0.6 mg m-3,基礎生產力為600–800 mg C m-2 day-1,同時符合前述三項海洋環境因子之條件值,經圖層套疊分析,可萃取出秋刀魚可能棲息海域(熱點)之時空分布。另外,利用地理權重迴歸(geographically weighted regression)模式,處理分析秋刀魚漁獲分布與海洋環境因子的空間非平穩型相關性。結果顯示,利用地理權重迴歸模式,可提高海洋環境因子對秋刀魚漁獲空間分布的解釋變異百分比,略高於目前常用的泛加成模式(generalized additive model)分析方法,故建議進行漁獲分布與海洋環境因子相關性分析時,應同時考量變數間之空間異質性(spatial heterogeneity)及相依性(spatial dependence)。再者,本論文亦探討不同海面水溫上升情境下(包含正常年及1、2、4°C水溫模式),秋刀魚可能棲息海域受氣候變遷影響之時空變動特性。結果顯示,秋刀魚的可能棲息海域,會隨著海面水溫上升,有逐漸往北推移的現象。其中,於水溫上升4°C模式下,秋刀魚可能棲息海域,往北推移的幅度最大,其南邊界線會往北推移至北緯46.15度。 綜合上述結果,本論文已完成探討西北太平洋臺灣遠洋秋刀魚漁獲之時空分布特性,並掌握海洋環境因子對秋刀魚魚群移動及洄遊分布之影響。這些分析結果可提供秋刀魚漁業資源管理策略參考,並作為未來發展秋刀魚漁海況速預報服務的重要基礎資訊。 | zh_TW |
dc.description.abstract | Five years (2006–2010) fishery data coupled with multi-sensor satellite images was examined to determine the habitat characterization for Pacific saury (Cololabis saira) in the northwestern Pacific Ocean (NWP). Results showed that monthly average CPUEs (metric tons/boat/day) ranged from 10.8 in early fishing season (June to August) to 23.1 in October. The overall average CPUE was 15.3. The major fishing grounds located within 37–48oN latitude and 145–165oE longitude with a remarkable latitudinal movement of the monthly mean centers of gravities.
Pacific saury’s habitat preferences in the Taiwanese fishing grounds were determined using the empirical cumulative distribution function. The high CPUEs corresponded to areas where sea surface temperature (SST) ranged from 14–16 oC, Chlorophyll-a (Chl-a) concentrations ranged from 0.4–0.6 mg m-3 and net primary productions (NPP) ranged from 600–800 mg C m-2 day-1. Local areas within the NWP with these similar satellite-derived oceanographic parameters were assumed to be the potential habitat zones of Pacific saury. Satellite SST data also were used to extract fronts in Pacific saury fishing grounds. The fronts were identified by the Cayula-Cornillon edge detection algorithm. The results show that low frequency of SST fronts is associated with lower saury’s CPUEs during the early fishing season (June to August). Conversely, high frequency of SST fronts is associated with higher saury’s CPUEs during the peak fishing season. Additionally, if the fishing locations of Pacific saury are close to the SST fronts, higher saury’s CPUEs are observed. The spatial non-stationary geographically weighted regression (GWR), a local modeling technique, was applied to examine the influence of oceanographic variability on the distribution of Pacific saury. The results of the GWR were compared with those of a generalized additive model (GAM). Results indicated that the distribution of Pacific saury is positively related to SST and Chl-a, and the GWR models explained more variability than the GAMs. Based on the SST preferences in concert with the corresponding fish distributions, monthly potential saury habitats were predicted. Possible changes in potential saury habitats were estimated under 4 scenarios: the present years and with 1, 2, and 4 °C rises in SST due to climate change. Results revealed an obvious poleward shift of potential saury habitats during the influence of increases in SSTs. The southernmost boundary of potential saury habitat located at 40.24°N latitude at the present time shifted to 46.15°N latitude under the scenario of a 4 °C rise in SSTs. In summary, the results obtained from this study improve our understanding of the variability in the spatial distribution of saury habitats, and could form the basis for fishery management and fishing forecasts. | en |
dc.description.provenance | Made available in DSpace on 2021-06-16T17:44:51Z (GMT). No. of bitstreams: 1 ntu-101-D94241007-1.pdf: 7107627 bytes, checksum: 06f797534646f4e692e73e4f0af70412 (MD5) Previous issue date: 2012 | en |
dc.description.tableofcontents | Table of contents
Chapter 1 – Introduction 1 1.1. Biology and ecology of Pacific saury 1 1.2. Oceanographic characteristics in the northwestern Pacific 2 1.3. Taiwanese deep-sea Pacific saury fishery 3 1.4. Review of Pacific saury studies 4 1.5. Review of satellite images application on fisheries 5 1.6. Objectives 6 Chapter 2 – Spatio-temporal analyses of Pacific saury distributions 8 2.1. Introduction 8 2.2. Materials and methods 9 2.2.1. Fishery data 9 2.2.2. Satellite data 10 2.2.3. Centre of gravity of fishing locations 11 2.2.4. Principal component analysis 12 2.3. Results 13 2.3.1. Taiwanese saury fishing grounds 13 2.3.2. Monthly CPUE distributions 14 2.3.3. Yearly CPUE distributions 15 2.3.4. Oceanographic variability of saury fishing ground 15 2.3.5. Hydrographic features of saury fishing ground 16 2.3.6. Effects of KOTZ on saury distributions 18 2.4. Discussion 19 2.4.1. Spatial variations of saury fishing grounds 19 2.4.2. Temporal variations of saury fishing grounds 20 2.4.3. Influence of environmental factors 20 2.4.4. Migratory pattern of Pacific saury 22 Chapter 3 –SST fronts effects on Pacific saury 24 3.1. Introduction 24 3.2. Materials and methods 26 3.2.1. Fishery data 26 3.2.2. Satellite data 26 3.2.3. Oceanic SST fronts detection 26 3.2.4. Relationship between SST fronts and Pacific Saury’s CPUE 27 3.3. Results 28 3.3.1. Distribution of Taiwanese Pacific saury fishery 28 3.3.2. SST fronts distributions and Pacific saury 28 3.3.3. Distance to SST fronts influence Pacific saury CPUEs 29 3.4. Discussion 30 3.4.1. Formations of SST fronts 30 3.4.2. SST fronts effects on Pacific saury 31 Chapter 4 –Spatial modelling of Pacific saury distributions 33 4.1. Introduction 33 4.2. Materials and methods 35 4.2.1. Data used 35 4.2.2. Graphical approaches 36 4.2.3. Statistical spatial models 37 4.3. Results 38 4.3.1. Environmental factors analysis 38 4.3.2. Preferable ranges of SST, Chl-a, NPP 39 4.3.3. Potential habitat zones of Pacific saury 40 4.3.4. Modelling the spatial non-stationarity of saury CPUE 41 4.4. Discussion 42 4.4.1. Oceanographic variability of saury fishing ground 42 4.4.2. Relationship between environmental factor and saury CPUE 43 4.4.3. Habitat hotspots of Pacific saury 43 4.4.4. Spatial modelling of saury distributions 44 Chapter 5 –Influence of rises in SSTs on saury’s habitats 46 5.1. Introduction 46 5.2. Materials and methods 47 5.2.1. Study area 47 5.2.2. Fishery data 48 5.2.3. Satellite data 48 5.2.4. Estimate of potential saury habitat 48 5.2.5. Effects of rises in sea surface temperatures 49 5.3. Results 49 5.3.1. Habitat distributions of the Pacific saury 49 5.3.2. SST preferences by the Pacific saury 50 5.3.3. Potential habitat of the Pacific saury 50 5.3.4. Latitudinal movement of the Pacific saury habitats 51 5.4. Discussion 52 5.4.1. Spatial changes in Pacific saury habitats 52 5.4.2. Potential saury habitats based on SST preferences 53 5.4.3. A poleward shift and shrinkage of potential saury habitats 54 Chapter 6 – Conclusions and recommendations 55 6.1. Conclusions 55 6.2. Recommendations 56 References 59 Figures 76 Tables 126 | |
dc.language.iso | en | |
dc.title | 衛星影像應用於臺灣秋刀魚漁業之漁海況變動研究 | zh_TW |
dc.title | Studies on the Fishing and Oceanographic Conditions of Taiwanese Pacific Saury (Cololabis saira) Fishery Using Multi-Sensor Satellite Images | en |
dc.type | Thesis | |
dc.date.schoolyear | 100-2 | |
dc.description.degree | 博士 | |
dc.contributor.oralexamcommittee | 蘇偉成,郭慶老,李國添,戴昌鳳,劉燈城 | |
dc.subject.keyword | 秋刀魚,衛星遙測影像,漁海況分析,經驗累積分布函數,地理權重迴歸,可能棲息海域, | zh_TW |
dc.subject.keyword | Pacific saury,satellite remote sensing image,fishing and oceanographic investigation,empirical cumulative distribution function,geographically weighted regression,potential habitat zone, | en |
dc.relation.page | 141 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2012-08-14 | |
dc.contributor.author-college | 理學院 | zh_TW |
dc.contributor.author-dept | 海洋研究所 | zh_TW |
顯示於系所單位: | 海洋研究所 |
文件中的檔案:
檔案 | 大小 | 格式 | |
---|---|---|---|
ntu-101-1.pdf 目前未授權公開取用 | 6.94 MB | Adobe PDF |
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。