土壤
土壤
토양
SOILS
2009年
5期
812-820
,共9页
模型%氮的优化%水稻%验证
模型%氮的優化%水稻%驗證
모형%담적우화%수도%험증
Model%Nitrogen optimization%Rice%Validation
在大量田间试验的基础上,建立了浙江水稻氮肥优化决策支持系统ONIR(optimazation of nitrogen to irrigated rice).该系统是利用NuDSS(nutrient decision support system)与独创的NSAM(N splitting application model)有机结合而成的.氮肥分次施用模型(NSAM)是根据水稻生长发育规律和养分平衡供应原理建立的,目的是确定各生育期的氮肥施用量,也就是氮肥的分次施用量.系统验证结果表明,模拟值与实测值均落在直观图1∶1线附近,线性回归t检验平均>0.05,斜率α在0.847 ~ 1.034 之间,确定系数R~2在0.85 ~ 0.99之间,均方差误差为1 ~ 110 kg/hm~2,规范均方根为 9% ~ 24%.在浙江水稻区,当目标产量为7.3 t/hm~2(晚稻)和8.3 t/hm~2(中稻)时,利用ONIR推荐的最佳氮肥用量分别为120 kg/hm~2和150 kg/hm~2;基肥、分蘖前期、幼穗分化期和抽穗期施肥的分配比例:晚稻为0.4∶0.2∶0.4∶0 或0.4∶0.2∶0.2∶0.2,中稻为0.4∶0.2∶0.4∶0 或者0.4∶0.2∶0.2∶0.2.
在大量田間試驗的基礎上,建立瞭浙江水稻氮肥優化決策支持繫統ONIR(optimazation of nitrogen to irrigated rice).該繫統是利用NuDSS(nutrient decision support system)與獨創的NSAM(N splitting application model)有機結閤而成的.氮肥分次施用模型(NSAM)是根據水稻生長髮育規律和養分平衡供應原理建立的,目的是確定各生育期的氮肥施用量,也就是氮肥的分次施用量.繫統驗證結果錶明,模擬值與實測值均落在直觀圖1∶1線附近,線性迴歸t檢驗平均>0.05,斜率α在0.847 ~ 1.034 之間,確定繫數R~2在0.85 ~ 0.99之間,均方差誤差為1 ~ 110 kg/hm~2,規範均方根為 9% ~ 24%.在浙江水稻區,噹目標產量為7.3 t/hm~2(晚稻)和8.3 t/hm~2(中稻)時,利用ONIR推薦的最佳氮肥用量分彆為120 kg/hm~2和150 kg/hm~2;基肥、分蘗前期、幼穗分化期和抽穗期施肥的分配比例:晚稻為0.4∶0.2∶0.4∶0 或0.4∶0.2∶0.2∶0.2,中稻為0.4∶0.2∶0.4∶0 或者0.4∶0.2∶0.2∶0.2.
재대량전간시험적기출상,건립료절강수도담비우화결책지지계통ONIR(optimazation of nitrogen to irrigated rice).해계통시이용NuDSS(nutrient decision support system)여독창적NSAM(N splitting application model)유궤결합이성적.담비분차시용모형(NSAM)시근거수도생장발육규률화양분평형공응원리건립적,목적시학정각생육기적담비시용량,야취시담비적분차시용량.계통험증결과표명,모의치여실측치균락재직관도1∶1선부근,선성회귀t검험평균>0.05,사솔α재0.847 ~ 1.034 지간,학정계수R~2재0.85 ~ 0.99지간,균방차오차위1 ~ 110 kg/hm~2,규범균방근위 9% ~ 24%.재절강수도구,당목표산량위7.3 t/hm~2(만도)화8.3 t/hm~2(중도)시,이용ONIR추천적최가담비용량분별위120 kg/hm~2화150 kg/hm~2;기비、분얼전기、유수분화기화추수기시비적분배비례:만도위0.4∶0.2∶0.4∶0 혹0.4∶0.2∶0.2∶0.2,중도위0.4∶0.2∶0.4∶0 혹자0.4∶0.2∶0.2∶0.2.
Based on the results of field fertilization experiments of rice conducted in Zhejiang Province, China, a decision support system for Optimization of Nitrogen to Irrigated Rice (ONIR) was developed, calibrated and validated. The system included NuDSS (the nutrient decision support system) and N Splitting Application Model (NSAM). NuDSS was a recently developed software for irrigated rice based on QUEFTS and SSNM, which was used to optimize nutrient management for rice varieties. According to NuDSS, the optimal fertilizer N requirement for the target yields could be calculated. We developed NSAM that could make sure N splitting application which based on the rhythm of growth and development of rice and nutrient balance. The results showed that the observed and simulated values of NA and DMA at different stages and grain yields at different N treatments fell near the 1:1 lines in the main. Values of α,R~2 were in the range of 0.847~1.034 and 0.85~0.99, respectively. All P(t~*) were larger than 0.05, yields absolute RMSE varied from 1 to 110 kg/hm~2 and normalized RMSE varied from 9% - 24%. The attainable target yields were set to 70 to 75 percents of their potential yields. The attainable targets of late rice and middle rice in Zhejiang were 7.3 and 8.3 t/hm~2 according to the potential yield simulated with WOFOST. On reasonable yield targets of late rice and middle rice in Zhejiang, the optimal fertilizer N requirement recommended by ONIR was about 120 kg/hm~2 with splitting fractions of 0.4:0.2:0.4:0 or 0.4:0.2:0.2:0.2 and 150 kg/hm~2 with splitting fractions of 0.4:0.2:0.2:0 or 0.4:0.2:0.2:0.2 as basal, at early tillering, panicle initiation and flowering stages, respectively. N application was only about 70% of the fertilizer N application under current farmers' practice. N input could be reduced in some degree without yield loss if rice N management practice were improved in Jinhua of Zhejiang Province.