Simulation Model of Growth Stages of Myrica rubra in Protected Cultivation Based on Meteorological Factors

doi:10.11923/j.issn.2095-4050.cjas2025-0118

Abstract

Abstract:

The simulation of the growth stages of Myrica rubra in protected cultivation is a key aspect in understanding the interaction between the growth of the plant and environmental factors. To explore the impact of the microclimate in protected cultivation on the growth stages of Myrica rubra and accurately predict the evolution of these stages, this study utilized growth and development data of Myrica rubra from 2022 to 2024 in Lanxi of Zhejiang, along with concurrent meteorological data on light, temperature, and other factors. Three methods were employed for the growth stage simulation: growing degree day (GDD), physiological development time (PDT), and the clock model. The models were validated based on their performance. The results indicated that the clock model exhibited higher predictive accuracy and adaptability in simulating the various growth stages of Myrica rubra, particularly during the reddening stage and maturity stages, where the prediction errors were significantly smaller compared to GDD and PDT methods. The root mean square errors (RMSE) for the wintering, flowering, fruit setting, reddening stage, and maturity stages in the clock model were 2.83 d, 3.32 d, 4.24 d, 2.38 d, and 2.16 d, respectively. The normalized root mean square errors (nRMSE) were 0.47, 1.11, 0.47, 0.48, and 0.54, respectively. These results demonstrate that the clock model provides a more accurate reflection of the growth stage evolution of Myrica rubra, offering scientific support for optimizing cultivation management strategies. This can effectively promote the implementation of refined management practices, improving both management efficiency and effectiveness. In the future, the parameters of wintering period can be optimized and extended to multi-variety and multi-region applications.

Key words: Myrica rubra, protected cultivation, growth stage simulation model, temperature-light effect, biological characteristics

CLC Number:

S162.5

JIAN Dan, WU Jianxin, ZHAO Rui, JIN Yang. Simulation Model of Growth Stages of Myrica rubra in Protected Cultivation Based on Meteorological Factors[J]. Journal of Agriculture, 2026, 16(5): 92-100.

Figures/Tables 7

References 36

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发育期	形态指标
越冬期	枝深褐至褐灰，芽体被覆褐色硬鳞片呈休眠态
开花期	花序簇生，雄蕊显露，雌花柱头颜色呈紫红色
坐果期	花序花落，种仁充实，果核硬化，果实膨大变色
转红期	果实由青绿色开始向淡红或浅紫转变
成熟期	果实呈现红色或紫红色，果实软硬适中不易损坏

发育期	形态指标
越冬期	枝深褐至褐灰，芽体被覆褐色硬鳞片呈休眠态
开花期	花序簇生，雄蕊显露，雌花柱头颜色呈紫红色
坐果期	花序花落，种仁充实，果核硬化，果实膨大变色
转红期	果实由青绿色开始向淡红或浅紫转变
成熟期	果实呈现红色或紫红色，果实软硬适中不易损坏

发育期	温度/℃			日照时数/h
发育期	下限温度T_m	最适温度(T_om~T_oM)	上限温度T_M	临界值D_L	最适值D_O
越冬期	0	10~15	25	2	12
开花期	2	10~20	25	2	12
坐果期	8	15~25	30	4	14
转红期	10	18~25	32	4	14
成熟期	15	20~30	35	2	12

发育期	温度/℃			日照时数/h
发育期	下限温度T_m	最适温度(T_om~T_oM)	上限温度T_M	临界值D_L	最适值D_O
越冬期	0	10~15	25	2	12
开花期	2	10~20	25	2	12
坐果期	8	15~25	30	4	14
转红期	10	18~25	32	4	14
成熟期	15	20~30	35	2	12

发育期	系数			模型
发育期	k	p	q	模型
越冬期	-2.04426	-0.05115	0.54237	$\frac{dM}{dt}=\frac{1}{D}={e}^{-0.04426}\times T{E}^{-0.05115}\times P{E}^{0.54237}$
开花期	-2.35149	-0.72681	0.85344	$\frac{dM}{dt}=\frac{1}{D}={e}^{-2.35149}\times T{E}^{-0.72681}\times P{E}^{0.85344}$
坐果期	-2.68462	-0.64178	0.56723	$\frac{dM}{dt}=\frac{1}{D}={e}^{-2.68462}\times T{E}^{-0.64178}\times P{E}^{0.56723}$
转红期	-0.17114	-0.55427	0.92371	$\frac{dM}{dt}=\frac{1}{D}={e}^{-0.17114}\times T{E}^{-0.55427}\times P{E}^{0.92371}$
成熟期	-1.76175	-0.84238	0.80514	$\frac{dM}{dt}=\frac{1}{D}={e}^{-1.76175}\times T{E}^{-0.84238}\times P{E}^{0.80514}$