Field Maize Yield Prediction Model Based on Causal Inference and Machine Learningin Agricultural Fields

doi:10.12133/j.smartag.SA202506027

Abstract

Abstract:

[Objective] Maize is one of the most important staple crops in the world and serves as a cornerstone of food security and agricultural sustainability. Accurate and timely prediction of maize yield is essential for optimizing agricultural management practices, supporting market regulation, and guiding policy decisions related to food supply and climate adaptation. In recent years, data-driven yield prediction methods based on machine learning and deep learning have achieved notable improvements in predictive accuracy. However, most existing approaches primarily rely on statistical correlations among variables and often treat influencing factors as independent predictors, without explicitly addressing the complex causal mechanisms and time-lagged interactions that govern crop growth processes. This limitation may lead to reduced model interpretability and compromised robustness under changing environmental conditions. To address these challenges, a novel maize yield prediction framework that integrates causal inference with a hybrid deep learning model was proposed, aiming to improve both predictive performance and mechanistic understanding. [Methods] Multi-source heterogeneous datasets collected across the maize growing season were utilized, including remote sensing-derived vegetation indices, meteorological variables (such as temperature and precipitation), soil profile moisture measurements at multiple depths, and crop observation data corresponding to key phenological stages. First, the Peter-Clark and momentary conditional independence (PCMCI) causal discovery algorithm was applied to systematically identify causal relationships between maize yield and its potential driving factors. The PCMCI method enables the detection of both contemporaneous and time-lagged causal links while effectively controlling for confounding effects in high-dimensional time series data. Through this process, the causal structure of yield formation was explicitly characterized, and key variables with statistically significant causal impacts were selected as inputs for the prediction model. Subsequently, a hybrid moving average, convolutional neural network-long short-term memory (MA-CNN-LSTM) model was constructed to capture the complex spatiotemporal patterns in the causally screened input variables. Specifically, a moving average module was employed as a preprocessing step to suppress high-frequency noise and enhance signal stability. A CNN was then used to extract latent correlation features among multiple variables, reflecting their joint influence on yield formation. Finally, an LSTM network was adopted to model temporal dependencies and cumulative effects across the growing season, enabling effective representation of dynamic yield responses. [Results and Discussions] The causal analysis revealed that soil moisture at depths of 10 cm and 50 cm exerted a significant positive influence on maize yield (P < 0.01), with deeper soil moisture showing a stronger and more persistent time-lagged effect. This finding highlighted the critical role of subsurface water availability in sustaining crop growth during later developmental stages. In addition, vegetation indiced such as the modified chlorophyll absorption ratio index and the normalized difference vegetation index exhibited significant short-term causal relationships with yield during the mid-growth stage of maize, indicating their sensitivity to canopy structure and photosynthetic activity during this period. Comparative experiments conducted against traditional statistical models and conventional machine learning approaches demonstrated that the proposed PCMCI-MA-CNN-LSTM framework consistently achieved superior predictive performance. On the test dataset, the coefficient of determination (R²) reached 0.955, while the mean absolute error (MAE) and root mean square error (RMSE) were reduced to 1.201 kg/mu and 1.474 kg/mu (1 hm²=15 mu). These results indicated that incorporating causal variable selection effectively enhances model accuracy and stability by reducing redundant and spurious correlations. [Conclusions] The results confirm that incorporating causal analysis into yield modeling provides a robust basis for identifying key driving variables and effectively enhances the accuracy and interpretability of maize yield prediction. The proposed framework offers a promising approach for precision agriculture and decision support in crop yield forecasting, particularly under complex and dynamic agro-environmental conditions.

Key words: peter-clark and momentary conditional independence (PCMCI), moving average, convolutional neural network, long short-term memory, yield prediction, machine learning, causal inference

CLC Number:

WANG Yi, CUI Xitong, WANG Chen, XIONG Baowei, SHAO Guomin, WANG Wanying, CAO Pei, HAN Wenting. Field Maize Yield Prediction Model Based on Causal Inference and Machine Learningin Agricultural Fields[J]. Smart Agriculture, 2026, 8(2): 175-187.

Figures/Tables 14

Fig. 1

Table 1

Table 2

Vegetation index and their calculation formulas

植被指数	公式	引用文献
EVI	$E V I = 2.5 × (R N I R - R R) / (R N I R + 6 × R R - 7.5 × R B + 1)$ （1）	［14］
GNDVI	$G N D V I = (R G - R R) / (R G + R R)$ （2）	［15］
NDVI	$N D V I = (R N I R - R R) / (R N I R + R R)$ （3）	［16］
SAVI	$S A V I = (1 + L) × (R N I R - R R) / (R N I R + R R + L)$ （4）	［17］
TCARI	$T C A R I = 3 × (R R E - R R) - 0.2 × (R R E - R G) × (R R E / R R)$ （5）	［18］
VARI	$V A R I = (R G - R R) / (R G + R R - R B)$ （6）	［19］
SR	$S R = R N I R / R R$ （7）	［20］
NDRE	$N D R E = (R N I R - R R E) / (R N I R + R R E)$ （8）	［21］
MCARI	$M C A R I = (R R E - R R) - 0.2 × (R R E - R G) × (R R E / R R)$ （9）	［22］

Table 2

Table 3

Fig. 2

Fig. 3

Fig. 4

Fig. 5

Table 4

Table 5

Fig. 6

Table 6

Fig. 7

Table 7

References 30

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数据类型	观测指标
作物数据	株高/cm、叶面积指数
气象数据	地面气压/hPa、平均气温/（℃）、降水量/mm、露点温度/（℃）、相对湿度/%、经向风速（U， m/s）、纬向风速（V， m/s）、太阳辐射净强度（net， J/（m²/d））、太阳辐射总强度（down， J/（m²/d））
土壤数据	土壤湿度（深度：10、20、30、40、50 cm）
遥感数据	增强植被指数（Enhanced Vegetation Index, EVI）、绿光归一化植被指数（Green Normalized Difference Vegetation Index, GNDVI）、归一化植被指数（Normalized Difference Vegetation Index, NDVI）、土壤调整植被指数（Soil-Adjusted Vegetation Index, SAVI）、转换叶绿素吸收比率指数（Transformed Chlorophyll Absorption in Reflectance Index, TCARI）、视觉大气阻力指数（Visible Atmospherically Resistant Index, VARI）、土壤饱和度（Simple Ratio, SR）、归一化差值红边（Normalized Difference Red Edge Index, NDRE）、归一化差分红边指数（Normalized Difference Red Edge Index, NDREI）、反射率中的改进叶绿素吸收指数（Modified Chlorophyll Absorption in Reflectance Index, MCARI）

名称	七叶期	拔节期	抽雄期	乳熟期
A区	6月25日	7月3日	7月28日	8月22日
B区	7月4日	7月10日	8月4日	8月27日
C区	7月13日	7月21日	8月13日	9月5日
D区	7月23日	7月30日	8月22日	9月18日

数据类型	时间滞后
数据类型	Lag 0	Lag 0—Lag 1	Lag 0—Lag 2	Lag 0—Lag 3
地面气压/hPa	▲
平均气温/°C	▲		▲
降水量/mm
露点温度/°C
相对湿度/%		●
经向风速/（m/s）	▲		▲	▲
纬向风速/（m/s）	▲			●
太阳辐射净强度/（W/m²）		▲	▲
太阳辐射总强度/（W/m²）		▲
土壤湿度10 cm	●	●	▲	●
土壤湿度20 cm		▲	●	▲
土壤湿度30 cm				▲
土壤湿度40 cm	●			▲
土壤湿度50 cm	▲	▲	▲	▲
株高/cm		▲	▲
叶面积指数/cm²				▲
EVI	▲
GNDVI		●	●
NDVI		▲
SAVI	●		●
TCARI			●
VARI			▲
SR		●
NDRE		●		●
MCARI	▲

Model	MAE/（kg/亩）	RMSE/（kg/亩）	R ²
SVR	2.363	2.943	0.821
CNN	2.007	2.564	0.864
LASSO	3.473	3.947	0.679
LSTM	1.833	2.217	0.898
MA-CNN-LSTM	1.201	1.474	0.955

Model	Factor		MAE/（kg/亩）	RMSE/（kg/亩）	R ²
Model	PCMCI	MA	MAE/（kg/亩）	RMSE/（kg/亩）	R ²
CNN-LSTM	×	×	1.798	2.105	0.908
	√	×	1.359	1.691	0.941
	×	√	1.564	1.924	0.923
	√	√	1.201	1.474	0.955