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¡¶±±·½Ô°ÒÕ¡·[ISSN:1001-0009/CN:23-1247/S]

Issue:

2016Äê11

Page:

41-45

Research Field:

Publishing date:

Info

Title:

Comparison of Effective Accumulated Temperature of Different Granularities inª¤ Simulating Development Stage of Cucumber in Greenhouse

Author(s):

CHEN Yuehao; XUE Qingyu; LI Zhenfa; LIU Shumei; LI Chun; GONG Zhihong

(Tianjin Climate Center£¬Tianjin 300074)ª¤

Keywords:

granularity; effective accumulated temperature; cucumber; development stage; simulation

PACS:

-

DOI:

10.11937/bfyy.201611011

Abstract:

According to the effective accumulated temperature(EAT) method£¬the growth and development of cucumber was simulated based on three different granularities temperature data in greenhouse.The results showed that the simulation error of seedling stage was maximum£¬the root mean square error(RMSE) was 12.4 days£¬the error of latest harvesting stage was minimum£¬RMSE was 1 days.Comparison of effective accumulated temperature of different granularity in simulating£¬the simulated error of effective accumulated temperature of days was minimum£¬the average error was -0.6 days£»the effective accumulated temperature of hours was -1.8 days£»the simulated error of effective accumulated temperature of 10 minutes was maximum£¬the average error was -2.2 days.This showed that the method of effective accumulated temperature was simulated in development stage of crops£¬the effective accumulated temperature of days was used of simulating in development stage of crops£¬the simulation result was better.In addition£¬three granularities of effective accumulated temperature were simulated in different development stages of cucumber£¬the simulation results of the development stages were basically identical except seedling stage£¬no obvious difference was showed.The error of transplanting stage was 5 days and 4 days£¬the flowering and fruit setting stage was -4 days£¬the harvesting stage was 3 days£¬and the latest harvesting stage was 1 days.Therefore£¬the method of effective accumulated temperature was not sensitive to different granularities accumulated temperature£¬and it was sensitive to change of diurnal temperature.ª¤

References:

 

[1]CURRY R B.Dynamic simulation of plant growth.I.Development of a model[J].ASAE Trans£¬1971£¬14(5):946-959.ª¤

[2]MONTIETH J L.The quest for balance in modeling[J].Agronomy Journal£¬1996,88:695-697.ª¤

[3]SINCLAIR T R£¬SELIGMAN N G.Crop modeling£ºfrom infancy to maturity[J].Agronomy Journal,1996,88:698-704.ª¤

[4]de WIT C T£¬BROUWER R£¬PENNING de VRIES F W T.The simulation of photosynthetic systems[C]//Setlik I.Prediction and management of photosynthetic productivity.Wageningen£¬The Netherlands£ºPUDOC,1970:47-70.ª¤

[5]de WIT C T.Simulation of assimilation£¬respiration and transpiration of crops[M].New York£ºWiley,1978.ª¤

[6]JONES C A£¬KINIRY J R£¬DYKE P T.CERES-Maize£ºA simulation model of maize growth and development[M].College Station£ºTexas A & M University Press£¬1986.ª¤

[7]RITCHIE J T£¬ALOCIJIA E C£¬UEHARA G.IBSNAT/CERES rice model[J].Agrotechnology Transfer,1986,3:1-5.ª¤

[8]RITCHIE J R£¬OTTER S.Description and performance of CERES-Wheat£ºa user-oriented wheat yield model[J].ARS-United States Department of Agriculture£¬Agricultural Research Service,1985:159-175.ª¤

[9]HOOGENBOOM G£¬JONES J W£¬BOOTE K J.Modeling growth£¬development£¬and yield of grain legumes using SOYGRO£¬PNUTGRO£¬and BEANGRO£ºA review[J].Trans ASAE£¬1992£¬35(6):2043-2056.ª¤

[10]MCCOWN R L£¬HAMMER G L£¬HARGREAVES J N G£¬et al.APSIM£ºa novel software system for model development£¬model testing and simulation in agricultural systems research[J].Agricultural Systems,1996,50(3):255-271.ª¤

[11]³Â½Ü.ÖйúÎÂÊÒ×÷ÎïÄ£ÐÍÑо¿×´¿ö[J].ÖйúÅ©»ú»¯,2012(2):29-32.ª¤

[12]лף½Ý,³Â´ººê,ÕÔ¾©Òô.×Ô¿ØÎÂÊһƹÏÉú³¤·¢Óý¶¯Ì¬¼°»ùÓÚÓÐЧ»ýεķ¢ÓýÄ£ÐÍÑо¿[J].ÉϺ£Å©ÒµÑ§±¨,2007,23(2):46-49.ª¤

[13]ÀîÏòÁë,ÕÔÃ÷,Àî´Ó·å,µÈ.ÓñÃ×Ò¶Ãæ»ýϵÊý¶¯Ì¬ÌØÕ÷¼°Æä»ýÎÂÄ£Ð͵Ľ¨Á¢[J].×÷Îïѧ±¨,2011,37(2):321-330.ª¤

[14]ÀîÁ¢À¥,ÀîÓñºì,³ÌÖÇ»Û,µÈ.»ùÓÚÓÐЧ»ýÎÂÔç´ºÉèÊ©ºñƤÌð¹Ï¹ûʵ·¢ÓýÄ£ÄâÄ£ÐÍ[J].±±·½Ô°ÒÕ,2010(6):97-100.ª¤

[15]ÑîÔÙÇ¿,ÂÞÎÀºì,³Â·¢é¦,µÈ.ÎÂÊÒ±ê×¼Çл¨¾Õ·¢ÓýÄ£ÄâÓëÊÕ»ñÆÚÔ¤²âÄ£ÐÍÑо¿[J].ÖйúÅ©Òµ¿Æѧ,2007,40(6):1229-1235.ª¤

[16]ÕÅÅàÐÂ,ºØ³¬ÐË,ÕÅÖ¾±ó,µÈ.»ùÓÚÉúÀí·¢Óýʱ¼äµÄÈÕ¹âÎÂÊÒ·¬ÇÑ·¢ÓýÄ£ÄâÄ£ÐÍ[J].ÖйúÅ©ÒµÆøÏó,2006,27(4):314-317.ª¤

[17]Ô¬²ý÷,ÂÞÎÀºì,ÕÅÉú·É,µÈ.ÎÂÊÒÍøÎÆÌð¹Ï·¢ÓýÄ£ÄâÄ£ÐÍÑо¿[J].Ô°ÒÕѧ±¨,2005,32(2):262-267.ª¤

[18]LIANCOURT P£¬LAURA A S£¬BAZARTSEREN B£¬et al.Vulnerability of the northern Mongolian steppe to climate change£ºInsights from flower production and phenology[J].Ecology,2012,93:815-824.ª¤

[19]CHRISTOPH R£¬PETER P.Land use affects flowering time£ºSeasonal and genetic differentiation in the grassland plant Scabiosa Columbaria[J].Evolutionary Ecology£¬2009,23(5):753-764.ª¤

[20]ÀîƼƼ,Öܾ²,Íõ¼ÍÕÂ,µÈ.ÎÂÊһƹÏÉúÓýÆÚÔ¤²âµÄÕýÏÒÖ¸ÊýÄ£ÐÍ[J].½­ËÕ´óѧѧ±¨,2009,30(4):325-329.ª¤

[21]ÕÅѧϼ,¸ðȫʤ,Ö£¾°ÔÆ.±±¾©µØÇøÆøºò±ä»¯ºÍÖ²±»µÄ¹Øϵ-»ùÓÚÒ£¸ÐÊý¾ÝºÍÎïºò×ÊÁϵķÖÎö[J].Ö²ÎïÉú̬ѧ±¨,2004,28(4):499-506.ª¤

[22]ÍõСÀ¼.À¼ÖÝÊÐÇø16ÖÖÊ÷ľ´º¼¾ÎïºòÆÚ¹Û²â[J].¸ÊËàÁÖÒµ¿Æ¼¼,2005,31(3):74-75.ª¤

[23]ÌÆÎÀ¶«,ÀîƼƼ,¬ÕÂƽ,µÈ.ÏÖ´úÎÂÊһƹϷ¢Óý¶¯Ì¬Ä£ÐÍÑо¿[J].°²»ÕÅ©Òµ¿Æѧ£¬2007,35(21):6421-6422.ª¤

[24]²ÜÔªöÎ,±ÏÑÓ¸Õ,Àî¾êÆð,µÈ.ÎÂÊһƹϷ¢ÓýÆÚÄ£ÄâÄ£Ð͵ļìÑé[J].ÖйúÅ©Òµ´óѧѧ±¨£¬2014,19(3):145-153.ª¤

[25]Ä߼ͺã,ÂÞÎÀºì,ÀîÓÀÐã,µÈ.ÎÂÊÒ·¬ÇÑ·¢ÓýÄ£ÄâÄ£ÐÍÑо¿[J].ÖйúÅ©Òµ¿Æѧ,2005,38(6):1219-1225.ª¤

[26]ʱСºì,¸ßÉê¾ü,ÐìѸ³¬.Ë®¹ûÐͻƹϸ߲úÔÔÅ༼Êõ[J].ºÓÄÏÅ©Òµ¿Æѧ,2002,1(1):36.ª¤

[27]ÍõÝæ,ÁõÊéͤ,ÑîÕñɽ,µÈ.ºÉÀ¼Î¢ÐͻƹÏÈÕ¹âÎÂÊÒÇﶬ²çÔÔÅ༼Êõ[J].ÖйúÊß²Ë,2004,1(1):49-50.ª¤

[28]ÕÅÕñÏÍ.Êß²ËÔÔÅàѧ[M].±±¾©£ºÖйúÅ©Òµ´óѧ³ö°æÉç,2003:142-143.ª¤

[29]³ÂË«³¼,ºØ³¬ÐË,ÕÅÖ¾±ó.ÊʺÏËÜÁÏ´óÅï·¬ÇÑÔ½Ïij¤¼¾½Ú¸ß²úÔÔÅàÆ·ÖÖÌØÐԱȽÏ[J].»ª±±Å©Ñ§±¨,2003,18(Ôö):81-85.ª¤

[30]ÑÏÃÀ´º,²ÜÎÀÐÇ,Àî´æ¶«,µÈ.СÂó·¢Óý¹ý³Ì¼°ÉúÓýÆÚ»úÀíÄ£Ð͵ļìÑéºÍÆÀ¼Û[J].ÖйúÅ©Òµ¿Æѧ,2000,33(2):43-50.ª¤

[31]ÕÅÁ¢èå,²ÜÎÀÐÇ,ÕÅ˼ƽ,µÈ.»ùÓÚÉúÀí·¢Óýʱ¼äµÄÃÞ»¨ÉúÓýÆÚÄ£ÄâÄ£ÐÍ[J].ÃÞ»¨Ñ§±¨,2003,15(2):97-103.

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Last Update: 2016-07-14