Yield Prediction Models in Guangxi Sugarcane Planting Regions Based on Machine Learning Methods

doi:10.12133/j.smartag.SA202304004

Abstract

Abstract:

[Objective] Accurate prediction of changes in sugarcane yield in Guangxi can provide important reference for the formulation of relevant policies by the government and provide decision-making basis for farmers to guide sugarcane planting, thereby improving sugarcane yield and quality and promoting the development of the sugarcane industry. This research was conducted to provide scientific data support for sugar factories and related management departments, explore the relationship between sugarcane yield and meteorological factors in the main sugarcane producing areas of Guangxi Zhuang Autonomous Region. [Methods] The study area included five sugarcane planting regions which laid in five different counties in Guangxi, China. The average yields per hectare of each planting regions were provided by Guangxi Sugar Industry Group which controls the sugar refineries of each planting region. The daily meteorological data including 14 meteorological factors from 2002 to 2019 were acquired from National Data Center for Meteorological Sciences to analyze their influences placed on sugarcane yield. Since meteorological factors could pose different influences on sugarcane growth during different time spans, a new kind of factor which includes meteorological factors and time spans was defined, such as the average precipitation in August, the average temperature from February to April, etc. And then the inter-correlation of all the meteorological factors of different time spans and their correlations with yields were analyzed to screen out the key meteorological factors of sensitive time spans. After that, four algorithms of BP neural network (BPNN), support vector machine (SVM), random forest (RF), and long short-term memory (LSTM) were employed to establish sugarcane apparent yield prediction models for each planting region. Their corresponding reference models based on the annual meteorological factors were also built. Additionally, the meteorological yields of every planting region were extracted by HP filtering, and a general meteorological yield prediction model was built based on the data of all the five planting regions by using RF, SVM BPNN, and LSTM, respectively. [Results and Discussions] The correlation analysis showed that different planting regions have different sensitive meteorological factors and key time spans. The highly representative meteorological factors mainly included sunshine hours, precipitation, and atmospheric pressure. According to the results of correlation analysis, in Region 1, the highest negative correlation coefficient with yield was observed at the sunshine hours during October and November, while the highest positive correlation coefficient was found at the minimum relative humidity in November. In Region 2, the maximum positive correlation coefficient with yield was observed at the average vapor pressure during February and March, whereas the maximum negative correlation coefficient was associated with the precipitation in August and September. In Region 3, the maximum positive correlation coefficient with yield was found at the 20‒20 precipitation during August and September, while the maximum negative correlation coefficient was related to sunshine hours in the same period. In Region 4, the maximum positive correlation coefficient with yield was observed at the 20‒20 precipitation from March to December, whereas the maximum negative correlation coefficient was associated with the highest atmospheric pressure from August to December. In Region 5, the maximum positive correlation coefficient with yield was found at the average vapor pressure from June and to August, whereas the maximum negative correlation coefficient as related to the lowest atmospheric pressure in February and March. For each specific planting region, the accuracy of apparent yield prediction model based on sensitive meteorological factors during key time spans was obviously better than that based on the annual average meteorological values. The LSTM model performed significantly better than the widely used classic BPNN, SVM, and RF models for both kinds of meteorological factors (under sensitive time spans or annually). The overall root mean square error (RMSE) and mean absolute percentage error (MAPE) of the LSTM model under key time spans were 10.34 t/ha and 6.85%, respectively, with a coefficient of determination R_v²of 0.8489 between the predicted values and true values. For the general prediction models of the meteorological yield to multiple the sugarcane planting regions, the RF, SVM, and BPNN models achieved good results, and the best prediction performance went to BPNN model, with an RMSE of 0.98 t/ha, MAPE of 9.59%, and R_v²of 0.965. The RMSE and MAPE of the LSTM model were 0.25 t/ha and 39.99%, respectively, and the R_v² was 0.77. [Conclusions] Sensitive meteorological factors under key time spans were found to be more significantly correlated with the yields than the annual average meteorological factors. LSTM model shows better performances on apparent yield prediction for specific planting region than the classic BPNN, SVM, and RF models, but BPNN model showed better results than other models in predicting meteorological yield over multiple sugarcane planting regions.

Key words: meteorological factor, HP filter, sugarcane yield, BPNN model, LSTM model, machine learning

CLC Number:

S566.1

SHI Jiefeng, HUANG Wei, FAN Xieyang, LI Xiuhua, LU Yangxu, JIANG Zhuhui, WANG Zeping, LUO Wei, ZHANG Muqing. Yield Prediction Models in Guangxi Sugarcane Planting Regions Based on Machine Learning Methods[J]. Smart Agriculture, 2023, 5(2): 82-92.

Figures/Tables 12

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产量/（t·ha^-1）	蔗区1	蔗区2	蔗区3	蔗区4	蔗区5
最大值	161.60	91.02	96.72	96.65	126.89
最小值	54.59	58.28	51.75	62.17	37.60
平均值	91.03	72.24	71.01	78.47	66.27

最优参数	蔗区1	蔗区2	蔗区3	蔗区4	蔗区5
n_estimators	5	10	5	5	10
max_depth	3	5	5	11	7
max_features	14	14	4	7	4

蔗区	气象因子	与产量的相关系数	影响时段
蔗区1	日照时数	-0.766	10—11月
	平均2分钟风速	-0.617	10—11月
	最大风速	-0.583	4—5月
	最小相对湿度	0.473	11月
	平均水气压	0.454	6月
蔗区2	平均水气压	0.663	2—3月
	最低气温	0.648	2—3月
	最低气压	-0.606	3月
	平均气温	0.596	2—4月
	20时至第二天20时降水量	0.527	8月
蔗区3	20时至第二天20时降水量	0.776	8—9月
	日照时数	-0.555	8—9月
	最低气温	0.542	3月
	平均水气压	0.487	3月
	最高气温	-0.465	8—11月
蔗区4	最高气温	-0.672	8—12月
	平均气温	-0.570	7—12月
	20时至第二天20时降水量	0.657	3—12月
	日照时数	0.502	5月
	最低气温	-0.448	8月
蔗区5	平均水气压	0.829	6—8月
	平均相对湿度	0.715	2—10月
	最低气压	-0.697	2—3月
	最高气压	-0.696	2—3月
	20时至第二天20时降水量	-0.437	6—7月

蔗区	本研究方法		对照方法
蔗区	RMSE/（t·ha^-1）	MAPE/%	RMSE/（t·ha^-1）	MAPE/%
蔗区1	24.34	11.88	37.125	32.29
蔗区2	9.25	9.37	14.145	18.19
蔗区3	8.51	10.05	23.64	36.80
蔗区4	5.04	5.62	9.02	9.71
蔗区5	11.37	18.08	17.67	29.75

蔗区	本研究方法		对照方法
蔗区	RMSE/（t·ha^-1）	MAPE/%	RMSE/（t·ha^-1）	MAPE/%
蔗区1	17.94	8.76	33.20	34.57
蔗区2	9.71	10.34	16.88	16.62
蔗区3	11.01	14.13	18.71	22.27
蔗区4	9.47	6.92	18.36	14.14
蔗区5	11.98	19.99	16.86	24.92