不同品种和氮素条件下水稻茎鞘夹角动态模拟

doi:10.3864/j.issn.0578-1752.2012.21.004

Abstract

Abstract: 【Objective】The objective of this paper is to develop a dynamic simulation model on angle between stem and sheath at different leaf positions on main stem in different rice cultivars and nitrogen application rates.【Method】Based on rice experiments with different cultivars and nitrogen rates, the values of angel between stem and sheath of different leaf positions on main stem during different development stages were continuously observed, a dynamic simulation model for changes of angle between sheath and stem at different leaf positions on main stem was developed by using dynamic modeling technology. 【Result】 Rice angle between stem and sheath increased with leaf development progress, the duration from the beginning of angle formation to the maximal value was about three leaf ages and the angles increased with the increasing nitrogen rates. From the first leaf to the third leaf, the maximum angle between stem and sheath at each leaf position increased with the increasing leaf position, and then decreased with the increase of leaf position. The logistic equation could be used to describe the change process of the angle between stem and sheath on main stem with growing degree days (GDD) in different varieties and nitrogen rates, and the maximum angle between stem and sheath with leaf position on main stem could be described with linear piecewise function. A variety parameter (the maximum angle between stem and sheath at the third leaf position) was introduced to quantify the variety characteristics on the angle between stem and sheath. Nitrogen factor was also used to reflect the effect of nitrogen on the angle between stem and sheath. 【Conclusion】A set of independent pot and pool experiments data were used to test the model, and the root mean square error (RMSE) between observed and simulated values was 2.31° and 2.78°, respectively, and the relative RMSE (RRMSE) was 11.56% and 14.77%, respectively, which indicated that the model has a good performance on predicting the angle between stem and sheath at different leaf positions on main stem. These results would provide technological support for the visualization of rice plant.

Key words: rice, angle between stem and sheath, simulation model

ZHANG Yong-Hui, TANG Liang, LIU Xiao-Jun, CAO Wei-Xing, ZHU Yan. Dynamic Simulation on Angle Between Stem and Sheath in Different Rice Cultivars and Nitrogen Rates[J].Scientia Agricultura Sinica, 2012, 45(21): 4361-4368.

References

[1]曹宏鑫, 石春林, 金之庆. 植物形态结构模拟与可视化研究进展. 中国农业科学, 2008, 41(3): 669-677.

Cao H X, Shi C L, Jin Z Q. Advances in researches on plant morphological structure simulation and visualization. Scientia Agricultura Sinica, 2008, 41(3): 669-677. (in Chinese)

[2]Fournier C, Andrieu B, Ljutovac S, Saint-Jean S. ADEL-wheat: a 3D architectural model of wheat development//International Symposium on Plant Growth Modeling, Simulation, Visualization and Their Applications, 2003: 54-63.

[3]雷晓俊, 汤亮, 张永会, 姜海燕, 曹卫星, 朱艳. 小麦麦穗三维几何模型构建与可视化研究. 农业工程学报, 2011, 27(3): 179-184.

Lei X J, Tang L, Zhang Y H, Jiang H Y, Cao W X, Zhu Y. 3D geometric model and visualization of wheat spike. Transactions of the CSAE, 2011, 27(3): 179-184. (in Chinese)

[4]Fournier C, Andrieu B. A 3D model of maize development. Annals of Botany, 1998, 81: 233-250.

[5]杨娟, 赵明, 潘学标. 基于NURBS和VC++6.0的棉花生长可视化研究. 农业工程学报, 2006, 22(10): 159-162.

Yang J, Zhao M, Pan X B. Visualization of cotton growth based on NURBS and VC++ 6.0. Transactions of the CSAE, 2006, 22(10): 159-162. (in Chinese)

[6]Hanan J S, Hearn A B. Linking physiological and architectural models of cotton. Agricultural System, 2003, 75: 47-77.

[7]Watanabe T, Hanan J S, Room P M, Hasegawa T, Nakagawa H, Takahashi W. Rice morphogenesis, plant architecture and 3d modeling. Annals of Botany, 2005, 95(7): 1131-1143.

[8]石春林, 朱艳, 曹卫星. 水稻叶曲线特征的机理模型. 作物学报, 2006, 32(5): 656-660.

Shi C L, Zhu Y, Cao W X. Mechanism model for rice leaf curve character. Acta Agronomica Sinica, 2006, 32(5): 656-660. (in Chinese)

[9]杨红云, 罗威, 何火娇, 谢信楠. 水稻叶片形态三维建模与计算机模拟. 农机化研究, 2008(12): 33-36.

Yang H Y, Luo W, He H J, Xie X N. Rice leaf blade 3D morphology modeling and computer simulation. Journal of Agricultural Mechanization Research, 2008(12): 33-36. (in Chinese)

[10]刘宏伟, 吴斌, 张红英, 李芳, 邵延华. 水稻叶片几何模型及其可视化研究. 计算机工程, 2009, 35(23): 263-265.

Liu H W, Wu B, Zhang H Y, Li F, Shao Y H. Research on rice leaf geometric model and its visualization. Computer Engineering, 2009, 35(23): 263-265. (in Chinese)

[11]李云梅, 王人潮, 王秀珍, 沈掌泉. 椭圆分布函数模拟水稻冠层叶倾角分布. 生物数学学报, 2003, 18(1): 105-108.

Li Y M, Wang R C, Wang X Z, Shen Z Q. Simulating rice leaf angle inclination distribution by elliptical distribution function. Journal of Biomathematics, 2003, 18(1): 105-108. (in Chinese)

[12]常丽英. 水稻植株形态建成的模拟模型研究[D]. 南京: 南京农业大学, 2007: 69-80.

Chang L Y. Studies on simulation model of morphological development in rice plant [D]. Nanjing: Nanjing Agricultural University, 2007: 69-80. (in Chinese)

[13]Zhu Y, Chang L Y, Tang L, Jiang H Y, Zhang W Y, Cao W X. Modeling leaf shape dynamics in rice. NJAS - Wageningen Journal of Life Sciences, 2009, 57(1): 73-81.

[14]刘岩, 陆建飞, 曹宏鑫, 石春林, 刘永霞, 朱大威, 孙金英, 岳延滨, 魏秀芳, 田平平, 包太林. 基于生物量的水稻叶片主要几何属性模型研究. 中国农业科学, 2009, 42(11): 4093-4099.

Liu Y, Lu J F, Cao H X, Shi C L, Liu Y X, Zhu D W, Sun J Y, Yue Y B, Wei X F, Tian P P, Bao T L. Main geometrical parameter models of rice blade based on biomass. Scientia Agricultura Sinica, 2009, 42(11): 4093-4099. (in Chinese)

[15]Tivet F, Pinheiro B D S, Raissac M D, Dinggkuhn M. Leaf dimensions of rice tillers. Annals of Botany, 2001, 88: 507-511.

[16]Rinaldi M, Losavio N, Flagella Z. Evaluation and application of the OILCROP-SUN model for sunflower in southern Italy. Agricultural Systems, 2003, 78: 17-30.

[17]Confalonieri R, Debellini C, Pirondini M, Possenti P, Bergamini L, Barlassina G, Bartoli A, Agostoni E G, Appiani M. A new approach for determining rice critical nitrogen concentration. Journal of Agricultural Science, 2011, 149: 633-638.

[18]孟亚利. 基于过程的水稻生长模拟模型研究[D]. 南京: 南京农业大学, 2002: 34-64.

Meng Y L. A process-based simulation model for rice growth[D]. Nanjing: Nanjing Agricultural University, 2002: 34-64. (in Chinese)

[19]Hirose T. Development of the Monsi-Saeki theory on canopy structure and function. Annals of Botany, 2005, 95: 483-494.

[20]Campbell C S, Heilman J L, Mclnnes K J, Wilson L T, Medley J C, Wu G W, Cobos D R. Seasonal variation in radiation use efficiency of irrigated rice. Agricultural and Forest Meteorology, 2001, 110: 45-54.

[21]Zhang L, van der Werf W, Bastiaans L, Zhang S, Li B, Spiertz J H J. Light interception and utilization in relay intercrops of wheat and cotton. Field Crops Research, 2008, 107: 29-42.

[22]Ruiz R A, Bertero H D. Light interception and radiation use efficiency in temperate quinoa (Chenopodium quinoa Willd) cultivars. European Journal of Agronomy, 2008, 29: 144-152.

[23]Acreche M M, Briceno-Felix G, Martin Sanchez J A, Slafer G A. Radiation interception and use efficiency as affected by breeding in Mediterranean wheat. Field Crops Research, 2009, 110: 91-97.

[24]Maddonni G A, Otegui M E. Leaf area, light interception, and crop development in maize. Field Crops Research, 1996, 48: 81-87.

[25]Stewart D W, Costa C, Dwyer L M, Smith D L, Hamilton R I, Ma B L. Canopy structure, light interception, and photosynthesis in maize. Agronomy Journal, 2003, 95: 1465-1474.

[26]李艳大, 汤亮, 张玉屏, 朱相成, 曹卫星, 朱艳. 水稻冠层光截获与叶面积和产量的关系. 中国农业科学, 2010, 43(16): 3296-3305.

Li Y D, Tang L, Zhang Y P, Zhu X C, Cao W X, Zhu Y. Relationship of par interception of canopy to leaf. Scientia Agricultura Sinica, 2010, 43(16): 3296-3305. (in Chinese)

[27]朱相成, 汤亮, 张文宇, 曹梦莹, 曹卫星, 朱艳. 不同品种和栽培条件下水稻冠层光合有效辐射传输特征. 中国农业科学, 2012, 45(1): 34-43.

Zhu X C, Tang L, Zhang W Y, Cao M Y, Cao W X, Zhu Y. Transfer characteristics of canopy photo-synthetically active radiation in different rice cultivars under different cultural conditions. Scientia Agricultura Sinica, 2012, 45(1): 34-43. (in Chinese)

Related Articles 15

[1]	PENG TingShen, LU JiuYan, WU MeiLin, YAN YuXin, LIU HongZhou, NAN WenBin, QIN XiaoJian, LI Ming, GONG JunYi, LIANG YongShu. QTL Analysis of Yield-Related Traits in Both Huangnuo2^# and Changbai7^# of Perennial Chinese Rice [J]. Scientia Agricultura Sinica, 2026, 59(7): 1361-1379.
[2]	CUI JieHao, ZHANG Meng, WANG Qin, YU JiaYan, LIN Kun, LI ShangZe, LAN Heng, GENG YanQiu, ZHANG Qiang, GUO LiYing, SHAO XiWen. Evaluation of Lodging Resistance and Its Physiological Mechanisms in Japonica Rice Resources [J]. Scientia Agricultura Sinica, 2026, 59(7): 1420-1438.
[3]	YUAN HaoLiang, NIE Jun, LI Peng, LU YanHong, LIAO YuLin, XU ChangXu, LI ZhongYi, CAO WeiDong, ZHANG JiangLin. Effects of Co-Utilization of Chinese Milk Vetch and Rice Straw on Soil Phosphorus Composition and Phosphorus Activation of Paddy Field in Southern China [J]. Scientia Agricultura Sinica, 2026, 59(7): 1480-1491.
[4]	XU YangHaoJun, CHEN LiMing, YANG ShiQi, TANG YiFan, TAN XueMing, ZENG YongJun, PAN XiaoHua, ZENG YanHua. Effects of Long-Term Different Straw Returning Methods on Soil Organic Carbon, Nutrients and Aggregate Formation in Different Soil Layers of Double Cropping Rice Field [J]. Scientia Agricultura Sinica, 2026, 59(7): 1492-1506.
[5]	LI XingYu, HUANG Rong, XIAN YiMing, TIAN JiaoJiao, MA XiaoJin, YANG QiaoXi, LI Bing, WANG ChangQuan. Characteristics of Organic Carbon Fractions and Carbon Dioxide Emissions of Different Size Aggregates in Rice Field Soils in Response to Long-Term Fertilization [J]. Scientia Agricultura Sinica, 2026, 59(6): 1255-1271.
[6]	MA ZhaoHui, QUAN ChengZhe, CHENG HaiTao, YANG KanJie, LI XinRui, LÜ WenYan. The Breeding Goals and Strategies of Northeast Japonica Rice Under the Background of Zhongke Fa No.5 [J]. Scientia Agricultura Sinica, 2026, 59(5): 927-936.
[7]	CHEN Min, JIAO ZiLan, QIAO ChengBin, XU Hao, ZHANG Bi, MA DongHua, KONG WeiRu, WANG JingWen, SONG JiaWei, LUO ChengKe, LI PeiFu, TIAN Lei. Morpho-Physiological Responses and Adaptive Strategies of Rice Germplasm Accessions from Different Subspecies Under Salt Stress [J]. Scientia Agricultura Sinica, 2026, 59(4): 705-722.
[8]	GUO FuCheng, TANG HaiJiang, HAO XinYi, MA GuoLin, YANG JiuJu, HUANG LinFeng, TIAN Lei, WANG Bin, LUO ChengKe. Effects of Different Irrigation Methods on Water-Salt Transport, Rice Yield, and Water Use Efficiency in Saline Soil in Ningxia [J]. Scientia Agricultura Sinica, 2026, 59(4): 750-764.
[9]	LUO Wei, YU Hong, YUAN LiXin, WANG LingLing, ZHAO JinPeng, YIN Wei, WANG MingTian, WANG RuLin. Change of Geographic Distributions of Ratoon Rice in Sichuan- Chongqing Under Global Climate Change [J]. Scientia Agricultura Sinica, 2026, 59(4): 765-780.
[10]	ZHANG WeiJian, YAN ShengJi, SHANG ZiYin, TANG ZhiWei, WU LiuGe, LI JiaRui, CHEN HaoTian, DENG AiXing, ZHANG Jun, ZHANG Xin, ZHENG ChengYan, SONG ZhenWei. Methane Emissions from Paddy Fields: Not Entirely Attributable to Rice Cultivation [J]. Scientia Agricultura Sinica, 2026, 59(4): 824-833.
[11]	ZHU Shu, GUO ZhiPeng, SUN Ying. Functional Analysis of Rice Target of Rapamycin OsTOR in Regulating Root Elongation [J]. Scientia Agricultura Sinica, 2026, 59(3): 475-485.
[12]	LÜ WenYan, CHENG HaiTao, MA ZhaoHui, TIAN ShuHua. Discussion on Hybridization Breeding Technology and Strategy of Rice in the New Era of Breeding [J]. Scientia Agricultura Sinica, 2026, 59(2): 233-238.
[13]	LIAO TingLu, SHI YaFei, XIAO DongHao, SHE YangMengFei, GUO FuCheng, YANG JiuJu, TANG HaiJiang, LUO ChengKe. The Effect of Exogenous Nitroprusside on Sugar Metabolism in Rice Seedlings Under Alkaline Stress [J]. Scientia Agricultura Sinica, 2026, 59(2): 265-277.
[14]	LIU TianSheng, LIU GengYuan, ZHAO AnQi, YANG Xu, CAI MingXue, YANG AiWen, LOU MingXuan, LI MuKai, WANG Han, ZHANG YaLing. Pathogenic Population of Rice Bakanae Disease in Heilongjiang Province [J]. Scientia Agricultura Sinica, 2026, 59(2): 305-321.
[15]	WANG ZhongNi, LEI Yue, LI JiaLi, GONG YanLong, ZHU SuSong. Functions of ABC Transporter OsARG1 in Rice Heading Date Regulation [J]. Scientia Agricultura Sinica, 2026, 59(1): 1-16.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

Comments

Recommended 0

No Suggested Reading articles found!

Dynamic Simulation on Angle Between Stem and Sheath in Different Rice Cultivars and Nitrogen Rates

PDF

Cited

Abstract

Cite this article

share this article

References

Related Articles 15

Metrics

Comments

Recommended 0