Quality of harvested rice and its production are influenced by the timing of harvesting. Harvesting at the right stage gives the best yield and quality. The purpose of this research was to determine the best time for harvesting by using image processing technique. Parameters such as weight of florets, hue colour of florets, and hue colour of flag leaf were tested in the research. The trends of changes were observed in the process of maturity until the harvesting day. For Malaysia Rice (MR) variety 219, the corresponding hue value for florets maturation is 32.3o ±2o. In the period of maturity, the florets’ hue value decreased from green to yellow and then remained constant at 32o. The maturity process proceeded gradually from the florets at the outermost spikelet to florets at the basal part. Florets at the basal part were matured seven days later than the florets at the terminal part. Results show that the colour changes of the leaf were uneven and hence did not give a good correlation with maturity. It was observed that the weight for a matured floret increased rapidly towards maturity, but remained constant after it reached the mature stage. There were some losses in weight due to the decrease of moisture contents in florets. Finally, it was concluded that the maturity of paddy can be observed through the colour and weight of florets. The MR219 mature floret has the hue colour of 32.3o ±2o, and the mature floret can weigh up to 31.25 mg.
Keywords: paddy maturity, colour vision, hue, paddy morphology, grain, Oryza Sativa
DOI: 10.3965/j.ijabe.20140705.006

Citation: Choe Lip Haw, Wan Ishak Wan Ismail, Siti Kairunniza-Bejo, Adam Putih, Ramin Shamshiri. Colour vision to determine paddy maturity. Int J Agric & Biol Eng, 2014; 7(5): 55－63.

paddy maturity, colour vision, hue, paddy morphology, grain, Oryza Sativa

USDA. Grains: World Market and Trade. Circular series FG12-12. USDA Foreign Agriculture Service, 2012.

Abdul Rahman A B, Yon R, Abdullah S, Zakaria A, Omar O, Malik Z, Othman S, Azmiman A. Conversion of Kampong Ewa rice fields in Langkawi, Malaysia, into organic rice farming. Proceedings of the 4th International Crop Science Congress, Brisbane, Australia, 2004. Available at http://www.cropscience.org.au/icsc2004/poster/2/5/2/553_bakarar.htm. Accessed on [2012-05-15]

McIntyre I. Food prices rise, eat less rice. The Star, 2008. Available at http://thestar.com.my/news/story.asp?file=/2008/4/27/nation/20080427192044&sec=nation. Accessed on [2013-03-15]

BERNAS. Rice Types in Malaysia. Padiberas Nasional Berhad, 2013. Available at http://www.bernas.com.my/ index.php?option= com_content&view=article&id=90&Itemid =103. Accessed on [2013-03- 21]

Zuraida A R, Zulkifli A S, Habibuddin H, Naziah B. Regeneration of Malaysian Rice variety MR219 via somatic embryogenesis. J. Trop. Agric. And Fd. Sc., 2012; 39(2): 167–177.

Alias B I. Rice Variety MR219. MARDI Agromedia. 2001. Available at http://agromedia.mardi.gov.my/magritech/tech_ detail_fdcrop.php?id=346. Accessed on [2013-02-12]

Bernama. Pesawah Sekinchan hasil 13 tan metrik padi sehektar. MStar. 2008. Available at http://mstar.com. my/berita/cerita.asp?file=/2008/5/14/TERKINI/Rencana/Pesawah_Sekinchan_hasil_13_tan_metrik_padi_sehektar&sec=mstar_berita. Accessed on [2013-03-26]

Wang Y H, Li J Y. The Plant architecture of the rice (Oryza sativa). Plant Mol Biol, 2005; 59 (1): 75-84.

Rachmat R, Thahir R, Gummert M. The empirical relationship between price and quality of rice at market level in west java. Indonesian Journal of Agriculture Science, 2006; 7(1): 27-33

Datta S K D. Principle & practices of rice production. New York: John Willey & Sons, 1981.

Rickman J F, Gummert M. Rice Grain Quality, IRRI, Los Banos, Philippines. 2005.

Morris M L. Rice Production: A Training Manual and Field Guide to Small-Farm Irrigated Rice Production. Washington, DC: Peace Corps, Information Collection & Exchange Division. 1980.

Charlotte J. Colour, Value and Hue. 1995. Available at http://char.txa.cornell.edu/language/element/colour/colour.htm. Accessed on [2012- 12-12]

NCSU. Colour principles- hue, saturation, and value. NCSU. 2000. Available at http://www.ncsu.edu/scivis/ lessons/colormod-els/color_models2.html. Accessed on [2013-04-30]

Tiznado H M E, Velazquez D M, Contreras A J O, Meza A O. Prediction of days after anthesis of developing tomato (Solanum Lycopersicum) fruit from blossom-end changes in colour. American Journal of Agricultural and Biological Sciences, 2013; 8(3): 191-198.

Huzari Razali M, Ismail W I W, Ramli A R, Sulaiman M N, Harun M H. Prediction model for estimating optimum harvesting time for oil palm fresh fruit bunches. Journal of Food, Agriculture & Environment, 2011; 9 (3&4): 570-575.

Maruyama T, Tanji K K. Physical and Chemical processes of soil related to paddy drainage. Shinzan-sha Sci. Tech.

Tokyo. 1997. pp. 229.

Aurora D R, Briones V, Vidal A, Bienvenido. Composition and endosperm structure of developing and mature rice kernel. The International Rice Research Institute, Los Banos, Laguna, Philippines. 1968.

Luh B S W. RICE: Production & Utilization. New York : Van Nostrand Reinhold. 1980.

IRRI. Information Sheet: Pest-Rice leaf folder. IRRI—Rice Doctor. 2009. Available at http://www.knowledgebank.irri. org/RiceDoctor/information-sheets-mainmenu-2730/pests-mainmenu-2737/rice-leaffolder-mainmenu-2816.html. Accessed on [2013-04-18]

Laza R C, Parao F T, Akita S. Growth & carbon balance of a rice canopy in temperature-controlled conditions. Philipp J. Crop Sci, 1989; 14(2): 69-75.

MARDI. High Yielding Rice Varieties. MARDI— Document Library, 2013. Available at http://www.mardi. gov.my/c/document_library/get_file?uuid=bb09dde5-5bda-45ce-8d37-4eeeeb177cf4&groupId=10138. Accessed on [2013-04-29]