應用螢光光譜及螢光影像評估稻米之新鮮度

Hao-Gu Hsieh; 謝灝谷

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/40749

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	盧福明
dc.contributor.author	Hao-Gu Hsieh	en
dc.contributor.author	謝灝谷	zh_TW
dc.date.accessioned	2021-06-14T16:58:40Z	-
dc.date.available	2011-08-05
dc.date.copyright	2008-08-05
dc.date.issued	2008
dc.date.submitted	2008-07-28
dc.identifier.citation	1.李匡邦、許東明、何東英。1997。光譜化學分析。初版。台北：揚智。 2.行政院農業農委會。2000。稻米新鮮度品質檢測法：BTB-MR多粒米試管法。台北：行政院農業農委會。 3.周家琳。2006。應用近紅外光技術檢測單粒米含水率。碩士論文。台北：國立台灣大學生物產業機電工程研究所。 4.林清騫、黃文哲、廖添旺。1990。食品化學(第二冊)。初版。台中：精華。 5.林文雄、劉安妮、王長瑩、黃紹興。1997。臺灣主要稻作品種外觀辨識參考手冊。台北：臺灣省政府糧食處。 6.林連雄。2007。近紅外光影像及發光二極體檢測系統偵測白米內部品質之研究。博士論文。台北：國立台灣大學生物產業機電工程研究所。 7.洪梅珠、宋勳。1987。儲藏方式對稻穀倉儲期間品質之影響。台中區農業改良場研究彙報(14、15)：15-20。 8.洪梅珠、宋勳。2005。穀物品質與分級。台灣農家要覽農作篇（一），21-24。台北：豐年社。 9.曾瑞田。2001。小型近紅外光穀物水份測定器之研製。碩士論文。台北：國立臺灣大學生物產業機電工程學研究所。 10.馮丁樹。1994。稻穀乾燥原理。稻穀倉儲加工作業技術手冊。第一輯稻穀乾燥，1-12。台北：農業機械化研究發展中心。 11.盧訓。2000。不同鮮度之稻米其化學組成及澱粉理化特性變化之探討。稻作改良年報: 233-241。 12.盧訓。2001。稻米經儲藏後對其米粒理化特性之改變。中華農學會報2(3): 241-250。 13.聯合國農糧組織。2005。農業資料庫。網址：faostat.fao.org/site/291/default.aspx。上網日期：2007-09-25。 14.太田保夫。1985。イネという作物。初版。日本：PHP 研究所。 15.河野澄夫。1995。日本應用非破壞性品質檢驗技術在稻米研究之現況。稻米自動化專輯(2)：1-20。台北：行政院農業委員會。 16.夏賀元康、仲村彰敏、河野澄夫。2003。近赤外分光法による玄米の選別関すゐ研究-玄米ㄧ粒成份自動選別機の高速改良と測定精度の檢證。農業機械學会誌 65(3): 107-113。 17.野村信使、竹川昌和。1995。稻作部50年のあゆみ，77-78。北海道立中央農業試驗所。 18.Andersen, C. M., M. Vishart and V. K. Holm. 2005. Application of fluorescence spectroscopy in the evaluation of light-induced oxidation in cheese. J. Agric. Food Chem. 53: 9985-9992. 19.Andersen, C. M. and G. Mortensen. 2008. Fluorescence spectroscopy: A rapid tool for analyzing dairy products. J. Agric. Food Chem. 56: 720-729. 20.Angela M., M. S. Kim, Y. Tao, A. LeFcourt and Y. R. Chen. 2004. Safety inspection of cantaloupes and strawberries using multispectral fluorescence imaging techniques. ASAE Paper No. 043056. 21.Bull, C. R. 1991. Wavelength selection for near-infrared reflectance moisture meters. J. Agric. Eng. Res. 49(2): 113-125. 22.Champagne, E. T., K. L. Bett-Garber, C. C. Grimm, A. M. McClung, K. A. Moldenhauer, S. Linscombe, K. S. McKenzie, and F. E. Barton. 2001. Near-infrared analysis for prediction of cooked rice texture. Cereal Chem. 78(3): 358-362. 23.Chrastil, J. 1994. Effect of storage on the physicochemical properties and quality factors of rice. In “Rice Science and Technology”, ed. W. E. Mkarshall and J. I. Wadsworth, 49-81. New York: Marcel Dekker, Inc. 24.Chotimarkorn, C. and S. Nattiga. 2008. Oxidative stability of fried dough rice flour containing rice bran powder storage. LWT. 41: 561-568. 25.Dufour, E. and A. Riaublanc. 1997. Potentiality of spectroscopic methods for the characterization of darity products. LAIT. 77: 657-670. 26.Hachiya, M., N. Asanome, T. Goto and T. Noda. 2006. Research and development of evaluation for freshness of brown rice using fluorescence imaging method with an UV-Light excitation. Proceeding of 3rd ISMAB: 779-786, Korea. 27.Halliday, D., R. Resnick and K. S. Krane. 1992. Physics, 4th Edition. JOHN WILEY & SONS, INC. 28.Ingle, J. D. and S. R. Grouch. 1988. Spectrochemical Analysis., 323-351. Englewood Cliffs: Prentice-Hall. 29.Iwasaki, T. and T. Tani. 1967. Effect of oxygen concentration on deteriorative mechanisms of rice during storage. Cereal Chem. 44: 233. 30.Kang, S., M. S. Kim, K. Chao, I. Kim and Y. R. Chen. 2002. Chicken disease characterization by fluorescence spectroscopy. ASAE Paper No.023061. 31.Karoui, R., G. Cartaud and E. Dufour. 2006. Front-Face fluorescence spectroscopy as a rapid and nondestructive tool for differentiating various cereal rroducts: A preliminary investigation. J. Agric. Food Chem. 54: 2027-2034. 32.Kennedy, G. and B. Barbara. 2003. Analysis of food composition data on rice from a plant genetic resources perspective. Food Chem. 80(4): 589-896. 33.Kulmyrzaev, A. A., D. Levieux and E. Dufour. 2005. Front-Face fluorescence spectroscopy allows the characterization of mild hest treatments applied to milk. Relations with the denaturation of milk proteins. J. Agric. Food Chem. 53(3): 502-507. 34.Lam, H. and A. Proctor. 2003. Milled rice oxidation volatiles and odor development. Journal of Food Science 68(9): 2677-2681. 35.Lefcourt, A. M., M. S. Kim and Y. R. Chen. 2005. Detection of fecal contamination in apple calyx by multispectral laser-induced fluorescence. Tran. ASAE 48(4): 1587-1593. 36.Li, W. S. and J. T. Shaw. 1997. Determining the fat acidity of rough rice by near-infrared reflectance spectroscopy. Cereal Chem. 74(5): 556-560. 37.Marshall, W. E. and J. I. Wadsworth. 1994. Introduction. In “Rice Science and Technology”. ed. W. E. Marshall and J. I. Wadsworth, 1-15. New York: Marcel Decker. 38.Martens, H. and T. Naes. 1989. Method for calibration. In “Multivariate Calibration”. New York: John Wiley & Sons. 39.Martin, M. and M. A. Fitzgerald. 2002. Proteins in rice grains influence cooking properties. Journal of Cereal Science 36(3): 285-294. 40.Natsuga, M. and S. Kawamura. 2006. Visible and near-infrared reflectance spectroscopy for determining physicochemical properties of rice. Trans. ASAE(4): 1069-1076. 41.Noh H. K. and R. Lu. 2005. Hyperspectral reflectance and fluorescence for assessing apple quality. ASAE Paper No. 053069. 42.Noh H. K., Y. Peng and R. Lu. 2006. Integration of hyperspectral reflectance and laser induced fluorescence imaging for assessing apple maturity. ASAE Paper No.066182. 43.Shin, M. G., J. S. Rhee and T. W. Knon. 1985. Effects of amylase activity on changes in amylogram characteristics during storage of brown rice. Agric Biol Chem. 49: 2505-2508. 44.Sikorska E., A. Gliszczynska-Awiglo, I. Khmelinskii and M. Sikorski. 2005. Synchronous fluorescence spectroscopy of edible vegetable oils. Quantification of tocopherols. J. Agric. Food Chem. 53: 6988-6994. 45.Takeuchi A., Y. Saito, M. Kanoh, T. D. Kawahara, A. Nomura, H. Ishizawa, T. Matsuzawa and K. Komatsu. 2002. Laser-Induced fluorescence detection of plant and optimal harvest time of agricultural products (lettuce). Applied Engineering in Agriculture 18(3):361-366. 46.Veberg, A., G. Vogt and J. P. Wold. 2006. Fluorescence in aldehyde model systems related to lipid oxidation. LWT. 39: 562-570. 47.White, C. E. 1970. Principle of fluorescence. In “Fluorescence Analysis : A Practical Approach”, ed. R. J. Argauer, 5-35. New York: M. Dekker. 48.Wikipedia. 2007. Fluorescence. Available at: en.wikipedia.org/wiki/Fluorescent. Accessed 20 September 2007. 49.Webb, B. O. 1991. Rice quality and grades. In “Rice Utilization”, ed. B. S. Luh, 89-166. New York: Van Nostrand Reinhold. 50.Wulf, J. S., E. Mulugeta and M. Zude. 2003. Laser-Induced fluorescence spectroscopy (LIFS): Influencing factors on measurement. ASAE Paper No. 036117. 51.Yamashita, R. 1993. New technology in grain postharvesting, Farm Machinery Industrial Research Corp., Tokyo 101, Japan. 52.Yasumatsu, K. and S. Moritaka. 1964. Fatty acid compositions of rice lipid and their changes during storage. Agri. Biol. Chem. 28:257-264. 53.Zaidi F., H. Rouissi, S. Dridi, M. Kammoun, J. D. Baerdemaeker and R. Karoui. 2008. Front-Face fluorescence spectroscopy as a rapid and non-destructive tool for differentiating between sicili-sarde and comisana ewe’s milk during lactation period: A preliminary study. Food Bioprocess Technol. 1: 143-151. 54.Zeleny, L. and D. A. Coleman. 1938. Acidity in cereals and cereal products, its determination and significance. Cereal Chem. 15:580-595.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/40749	-
dc.description.abstract	本研究的目的是以螢光光譜與影像評估不同期別稻米的新鮮度。稻穀樣本從不同農會取得。實驗稻穀經過碾米過程得到糙米與白米樣本。稻穀、糙米與白米的螢光光譜反應是使用Jasco FP-6300螢光光譜儀進行量測。在激發光以365nm波長照射後，進行光譜掃描，其掃描範圍在400nm到600nm之間，即可獲得光譜反應資訊。分析螢光光譜之結果顯示，較舊白米樣本相對於較新樣本，有較強的螢光反應，且白米螢光強度高於相同期別之稻穀與糙米。在化學分析上，本研究使用BTB-MR法量測稻米之酸鹼度。在螢光峰值與酸鹼度之迴歸決定係數(R2)為0.72。以此方法辨別稻米新鮮度具有可行性。在影像方法中，量測系統是由4組UV-A汞燈與灰階式數位型CCD感測器所組成。本系統為實驗室基本型且設計架設於暗室內，測試不同期別稻米樣本相關影像反應。結果顯示相同期別之白米樣本螢光影像強度高於稻穀與糙米樣本。變異數分析結果指出2007年第一期和第二期的白米螢光影像強度具有顯著的差異。應用螢光影像判別白米新鮮度具有可行性。	zh_TW
dc.description.abstract	The objective of this project was to evaluate freshness of rice in different crop years using fluorescence spectrum and image. The paddy samples were obtained from different farmer’s associations. The experimental paddy was milled to obtain brown rice and white rice. The fluorescence responses of paddy rice, brown rice, and white rice were measured with Jasco FP-6300 Spectrofluorometer. The fluorescence responses were detected at wavelength in the range 400 nm to 600 nm after excitation at 365nm. The result shows that the aged white rice has stronger fluorescence response as compared to fresh sample. The white rice has strongest fluorescence response as compared to brown rice and paddy rice of the same crop year. In chemical analysis, this study used BTB-MR method to detect the pH value of rice. The coefficient of determination (R2) between the fluorescence peaks and pH value is 0.72.This result indicates that it is feasible to adopt fluorescence spectra to measure rice freshness. The fluorescence imaging system consists of four UV-A Hg lamps and a digital monochrome camera. The system is laboratory-based and is designed to be performed inside the darkened box. The fluorescence imaging system was tested for detecting rice in different crop year with respect to image response. The result shows that the white rice has strongest fluorescence image intensity as compared to brown rice and paddy rice in the same crop year. The significant difference in white rice fluorescence image intensity was found between the first and second crop of 2007. It is also feasible to adopt fluorescence imaging system to evaluate rice freshness.	en
dc.description.provenance	Made available in DSpace on 2021-06-14T16:58:40Z (GMT). No. of bitstreams: 1 ntu-97-R95631019-1.pdf: 3143718 bytes, checksum: 2ef8441c7d570e0cec5c90b04871d191 (MD5) Previous issue date: 2008	en
dc.description.tableofcontents	誌謝 i 摘要 ii Abstract iii 目錄 iv 圖目錄 vii 表目錄 xi 符號說明 xii 第一章前言 1 1.1 研究背景 1 1.2 研究目的 3 第二章文獻探討 4 2.1 稻米的簡介 4 2.1.1 稻米的生長範圍與產量 6 2.1.2 稻米的主要成分 8 2.1.3 貯藏期間稻米品質的變化 9 2.1.4 影響米飯食味的主要成份 11 2.2 非破壞性品質檢測 13 2.2.1 近紅外線光譜分析技術應用於穀物品質之相關研究 13 2.3 分子發光光譜與分析 15 2.3.1 光與物質之反應 15 2.3.2 分子發射光譜 19 2.3.3 螢光與磷光之簡介 20 2.3.4 螢光光譜之定量分析 22 2.4 螢光光譜與影像應用於農產品品質分析之研究 24 2.4.1 螢光光譜技術於農產品品質分析之研究 24 2.4.2 螢光光譜影像應用於農產品之相關研究 27 2.5 螢光與食品內部化學物質之反應 30 2.6 稻米螢光檢測之應用原理 31 第三章材料與方法 32 3.1 實驗樣本 33 3.2 儀器設備 36 3.2.1 螢光光譜儀 36 3.2.2 影像系統設備 39 3.3 實驗流程 46 3.3.1 稻米樣本螢光光譜掃描實驗流程 46 3.3.2 稻米螢光影像實驗流程及影像處理 50 3.4 化學分析 52 第四章結果與討論 53 4.1 螢光光譜掃描結果 54 4.1.1 不同激發光波段與光譜反應 54 4.1.2 螢光強度與白米白度值之關係 58 4.1.3 稻米螢光反應之結果 62 4.1.4 螢光光譜應用於稻米新鮮度評估 65 4.1.5 白米樣本之光譜處理與分析 70 4.2 影像分析 73 4.2.1 影像擷取 73 4.2.2 原始影像分析 74 4.2.3 螢光量化計算結果 79 4.2.4 白米樣本之相對螢光強度變異數分析 83 4.2.5 白米新舊期別混合實驗 85 第五章結論與建議 88 5.1 結論 88 5.2 建議 90 參考文獻 91
dc.language.iso	zh-TW
dc.subject	新鮮度	zh_TW
dc.subject	螢光	zh_TW
dc.subject	光譜	zh_TW
dc.subject	影像	zh_TW
dc.subject	稻米	zh_TW
dc.subject	image	en
dc.subject	rice	en
dc.subject	freshness	en
dc.subject	fluorescence	en
dc.subject	spectra	en
dc.title	應用螢光光譜及螢光影像評估稻米之新鮮度	zh_TW
dc.title	Applications of Fluorescence Spectra and Fluorescence Image in Evaluation of Rice Freshness	en
dc.type	Thesis
dc.date.schoolyear	96-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	李允中,盧虎生
dc.subject.keyword	稻米,新鮮度,螢光,光譜,影像,	zh_TW
dc.subject.keyword	rice,freshness,fluorescence,spectra,image,	en
dc.relation.page	95
dc.rights.note	有償授權
dc.date.accepted	2008-07-30
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	生物產業機電工程學研究所	zh_TW
顯示於系所單位：	生物機電工程學系

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