Light and Temperature Effects on Agronomic Indices of Brassica chinensis L. in a Simulated Greenhouse Test
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摘要:
目的 研究小白菜在温室环境下的农艺指标动态,揭示小白菜形态和产量形成过程。 方法 以耐热品种华冠小白菜为试材,在薄膜温室内开展水培试验。试验过程中,实时采集温室环境数据,并定期测定小白菜农艺指标。根据小白菜农艺指标与温度和光合有效辐射的关系,构建基于光温效应(LTF)的温室小白菜农艺指标动态模拟模型,并应用不同播期的试验数据对模型进行验证。 结果 结果表明,小白菜株高、叶数、叶面积、茎粗、根长、鲜重等农艺指标均随LTF的增加而增长,拟合方程可用S型生长曲线函数描述。LTF模型的预测效果优于辐热积(TEP)模型和积温(GDD)模型;其不仅改善了农艺指标的模拟精度,且拟合度较佳。各项农艺指标模拟值与实测值之间的决定系数(R2)为0.907~0.984;回归估计标准误差(RMSE)为0.540~34.393,相对误差(RE)为6.79%~12.66%,RMSE和RE分别为TEP、GDD模型的5.29%~59.98%、31.30%~96.23%。 结论 基于LTF的模型预测值与实测值吻合度较好,预测精度较高,可为温室小白菜生长模拟提供参考。 Abstract:Objective By studying changes on the agronomic properties of Brassica chinensis L. in response to the light and temperature conditions in a greenhouse, morphology and yield of the plant were investigated. Method A hydroponics experiment with a heat-resistant B. chinensis in a greenhouse was carried out. The environmental data were collected in real time, and the agronomic properties of the plants monitored continuously. Relationship between the plant agronomy and the greenhouse temperature and photosynthetically active radiation (or, the light and temperature function, LTF) was used to compare with other dynamic simulation models. Result The agronomic indices including plant height, leaf number, leaf area, stem diameter, root length, and fresh weight of B. chinensis increased with increasing LTF in a fitting equation of an s-shaped function. Prediction by the LTF-based model was better than either TEP- or GDD-based model. The LTF model was not only more precise but also better fitted between the simulated and measured agronomic indices. It showed a R2 of 0.907-0.984, a RMSE of 0.540-34.393, and a RE of 6.79-12.66%, which were superior to the RMSE and RE of 5.29-59.98% and 31.30-96.23% for TEP and GDD models, respectively. Conclusion The LTF-based model was found to more accurately predict the growth and yield of B. chinensis than did the other models. -
Key words:
- Greenhouse /
- Brassica chinensis L. /
- light and temperature function /
- agronomy /
- simulation
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图 1 小白菜单株株高(a)、叶数(b)、叶面积(c)、茎粗(d)、根长(e)、鲜重(f)与光温效应、辐热积以及积温的关系
Figure 1. Individual plant height (a), leaf number (b), leaf area (c), stem diameter (d), root length (e), and fresh weight (f) of B. chinensis in relation to LTF, TEP or GDD
图 2 小白菜单株株高(a)、叶数(b)、叶面积(c)、茎粗(d)、根长(e)、鲜重(f)模拟值和实测值比较
Figure 2. Simulated vs. measured individual plant height(a), leaf number(b), leaf area(c), stem diameter(d), root length(e), and fresh weight(f) of B. chinensis
表 1 试验期间环境温度和光合有效辐射情况
Table 1. Ambient temperature and photosynthetically active radiation applied for experimentation
试验期
Experiment天数
Days/d日平均气温
Daily average temperature/℃日光合有效辐射
Daily photosynthetically active radiation/(mol·m−2·d−1)最大值
Maximum最小值
Minimum均值
Mean最大值
Maximum最小值
Minimum均值
Mean1 32 35.87 27.47 33.51 16.86 3.61 10.65 2 36 36.38 31.62 34.51 19.58 0.001 8.18 3 30 34.83 31.25 33.26 19.30 7.67 13.64 
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表 2 小白菜单株株高、叶数、叶面积、茎粗、根长、鲜重与光温效应、辐热积以及积温的拟合结果
Table 2. Individual plant height, leaf number, leaf area, stem diameter, root length, and fresh weight of B. chinensis as affected by LTF, TEP or GDD
指标
Index方程
EquationR2 RMSE 指标
Index方程
EquationR2 RMSE 株高
Plant height23.539 3 EXP[−EXP
(0.393 9−0.150 7 LTF)]0.960 1.097 茎粗
Stem diameter−16.657 9 EXP[−EXP
(1.017 2−0.068 5 LTF)]0.980 0.310 −18.353 2/[1+(TEP/53.802 0)1.973 3]+
24.050 80.956 1.156 −17.041 5 EXP[−EXP
(1.066 5−0.009 5 TEP)]0.979 0.314 −18.227 9/[1+(GDD/346.882 2)1.851 7]+
23.986 20.964 1.047 12.428 7 EXP[−EXP
(0.950 0−0.001 7 GDD)]0.985 0.263 叶数
Leaf number−20.385 1/[1+(LTF/18.317 6)3.270 0]+
24.868 90.989 0.420 根长
Root length−28.524 1/[1+(LTF/18.260 6)1.2605 9]+
32.544 80.976 0.755 −29.309 3/[1+(TEP/154.911 0)2.998 7]+
33.748 20.987 0.451 −24.971 9/[1+(TEP/101.637 62)1.413 29]+
28.806 060.971 0.836 −16.807 5/[1+(GDD/785.289 5)3.442 2]+
21.349 90.988 0.434 −24.030 76/[1+(GDD/659.621 19)1.338 13]+
27.959 840.973 0.802 叶面积
Leaf area26 248 000 EXP[−EXP
(2.613 8−0.014 5 LTF)]0.978 39.761 鲜重
Fresh weight8 347.241 8 EXP[−EXP
(2.153 1−0.034 2 LTF)]0.967 5.696 30.496 0−1.419 1 TEP+0.054 9 TEP2 0.963 51.538 4 037 040 EXP[−EXP
(2.680 0−0.002 43TEP)]0.972 5.256 34 100.942 0 EXP[−EXP
(1.964 9−0.000 7 GDD)]0.984 34.089 −1 006.914 6 EXP[−EXP
(1.895 8−0.001 1 GDD)]0.971 5.311
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表 3 基于光温效应、辐热积以及积温的小白菜单株株高、叶数、叶面积、茎粗、根长、鲜重模型检验结果
Table 3. Test results of LTF, TEP and GDD models on individual plant height, leaf number, leaf area, stem diameter, root length, and fresh weight of B. chinensis
指标
Index拟合方法
Fitting methodR2 RMSE RE(%) 指标
Index拟合方法
Fitting methodR2 RMSE RE(%) 株高
Plant heighLTF 0.946 1.106 6.79 茎粗
Stem diameterLTF 0.936 0.540 12.66 TEP 0.874 1.843 11.32 TEP 0.744 1.415 33.18 GDD 0.943 1.200 7.38 GDD 0.897 0.712 16.69 叶数
Leaf numberLTF 0.966 0.697 8.24 根长
Root lengthLTF 0.907 1.338 9.97 TEP 0.346 6.586 77.89 TEP 0.763 2.494 18.59 GDD 0.947 0.998 11.81 GDD 0.912 1.390 10.36 叶面积
Leaf areaLTF 0.981 34.393 11.21 鲜重
Fresh weightLTF 0.984 3.733 11.83 TEP 0.630 297.276 96.91 TEP 0.463 70.648 223.80 GDD 0.891 109.891 35.82 GDD 0.922 10.637 33.69
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