AgriAgent: End-to-End Large Model Agent System Architecture for Agricultural Environment Control

doi:10.12133/j.smartag.SA202507042

Abstract

Abstract:

[Objective] Large language models (LLMs) have demonstrated strong capabilities in natural language understanding, knowledge integration, and complex reasoning, offering new opportunities for intelligent decision-making in agriculture. However, their direct application in agricultural production and facility environment control remains challenging due to strong physical constraints and high operational risks. The lack of real-world interaction and executable decision grounding limits the practical effectiveness of conventional LLMs in such scenarios. To address these challenges, a tool-augmented LLM-based agricultural intelligent agent system, termed AgriAgent, was proposed, and a digital-twin-based evaluation platform for agricultural decision-making was developed. By integrating a high-fidelity digital twin environment with an end-to-end agent architecture, the decision-making performance of agricultural intelligent agents with different parameter scales was systematically evaluated across multiple crops and climate scenarios. [Methods] A high-fidelity agricultural digital twin evaluation platform was constructed using the decision support system for agrotechnology transfer (DSSAT) v4.8 crop growth model as the core simulation engine to model crop growth under diverse environmental conditions and management strategies. Meteorological driving data were obtained from the Seoul Historical Weather Data dataset. Through data cleaning, missing-value imputation, unit normalization, and time-series reconstruction, the raw meteorological data were transformed into standardized inputs compatible with DSSAT. Three climate scenarios representing different environmental complexities were designed, including a regular scenario, a perturbed scenario, and an extreme scenario. The regular scenario employed historical observations, the perturbed scenario introduced stochastic disturbances to simulate short-term climate variability, and the extreme scenario incorporated multi-factor coupled stresses such as high temperatures and excessive precipitation during sensitive growth stages. In total, 90 annual climate driving sequences were generated. Fixed soil profile parameters calibrated by domain experts were applied across all simulations to minimize confounding effects. Within this digital twin environment, a tool-augmented agricultural intelligent agent, AgriAgent, was implemented using a modular architecture consisting of a sensor module, memory module, retriever, large language model, and tool executor, forming a closed-loop decision-making framework. In each decision cycle, the agent perceived environmental and crop state information, including soil moisture and nutrient status, meteorological conditions, crop growth stages, and stress indicators. State summaries and historical decisions were stored in memory, while agronomic knowledge was retrieved through a retrieval-augmented generation mechanism. Based on integrated information, the LLM generated structured environmental control commands in JSON format, which were validated and constrained by the tool executor before updating the DSSAT environment. The system supported irrigation, supplementary lighting, ventilation, heating, fertilization, and CO₂ enrichment. Five representative crops: maize, millet, sugar beet, tomato, and cabbage were simulated under the three climate scenarios over complete growing seasons, resulting in 450 crop-scenario combinations. An unmanaged DSSAT simulation served as the baseline. AgriAgent models with three parameter scales (1.5B, 3B, and 7B), built on the Qwen2.5 series, were evaluated. Crop economic yield expressed as dry matter at physiological maturity was adopted as the evaluation metric. [Results and Discussions] The results showed that AgriAgent consistently outperformed the baseline across all crops and climate scenarios, with model scale exerting a significant influence on decision-making performance. AgriAgent-7B achieved the best overall performance under regular, perturbed, and extreme scenarios, demonstrating strong generalization ability and environmental adaptability. By dynamically adjusting water, nutrient, light, and thermal management strategies, the agent effectively mitigated environmental stresses even under multi-factor coupled extreme climate conditions. Under extreme scenarios, AgriAgent-7B increased yields by 463.60% for maize, 351.20% for millet, 125.40% for sugar beet, 1 537.46% for tomato, and 1 185.14% for cabbage compared with the baseline. Particularly large gains were observed for high-value crops such as tomato and cabbage, highlighting the advantages of the proposed framework for precision-controlled facility agriculture. In contrast, AgriAgent-1.5B exhibited performance comparable to the baseline, while AgriAgent-3B achieved moderate improvements but remained inferior to the 7B model. These findings indicate a clear scaling effect, suggesting that larger models possess stronger capabilities in multi-source information integration, long-term temporal reasoning, and adaptation to complex environments. [Conclusions] This study developed a digital-twin-based agricultural decision evaluation platform and proposed a tool-augmented, end-to-end agricultural intelligent agent named AgriAgent. Experiments across multiple crops and climate scenarios verified the effectiveness and robustness of the proposed framework for dynamic agricultural decision-making. The results demonstrate that integrating knowledge retrieval, reasoning, and tool execution within a closed-loop LLM-based agent enables stable, reliable, and adaptive environmental control, providing a feasible technical pathway and standardized evaluation paradigm for intelligent agriculture.

Key words: tool-augmented large language model, agricultural agent, digital twin, agricultural evaluation platform, DSSAT/crop growth model

CLC Number:

S126
TP18

QIU Jiaying, LIU Yingchang, GAO Xingjie, HUANG Yuan, ZHANG Hongyu, TIAN Fang, LI Wanli, FENG Zaiwen. AgriAgent: End-to-End Large Model Agent System Architecture for Agricultural Environment Control[J]. Smart Agriculture, 2026, 8(2): 220-236.

Figures/Tables 13

Fig. 1

Table 1

AgriAgent control system model

设备	控制动作符号	范围/分辨率	主要影响
灌溉系统	I	0~30 mm/h	提升 $W s o i l$
补光系统	L	0~200%	提升光合有效辐射
通风/加温	V，H	0/1（开关）	调节 $T a v g, W S$
施肥系统	F	0~50 kg/hm²	增加 $N t o t a l$
CO₂施放	C	0~800 μmol/mol/h	提升室内CO₂

Table 1

Fig. 2

Fig. 3

Table 2

Core functions and key implementation points of AgriAgent system components

模块	功能摘要	实现要点
传感器	从仿真环境读取状态向量 $s t$	以API形式模拟真实传感器
记忆库	持久化存储全局状态摘要	以文本形式保存在System prompt中
格式转换器	将结构化状态拼接为自然语言片段	以固定规则实现
检索器（Retriever）	面向知识库检索作物生理模型、控制经验	以Faiss检索实现
LLM	解析环境信息并生成JSON格式工具调用	经过预训练和后训练的大语言模型
工具执行器	校验、裁剪并调用修改DSSAT 的接口	Python实现

Table 2

Table 3

Fig. 4

Table 4

Fig. 6

Table 5

Table 6

Table 7

Table 8

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土层深度/cm		［0，20）	［20，40）	［40，60）	［60，80）	［80，100）
颗粒组成/%	黏粒	21.6	21.4	20.8	11.2	10.4
	粉粒	78.4	78.6	78	78.1	69.3
	砂粒	0.0	0.0	1.2	10.7	20.3
土壤容重/（g/cm³）		1.47	1.44	1.52	1.54	1.46
田间持水量/（cm³/cm³）		0.306 0	0.274 9	0.319 1	0.375 6	0.328 8
永久凋萎点/（cm³/cm³）		0.080 6	0.095 2	0.093 1	0.072 3	0.093 1
土壤有机碳/%		1.0	0.5	0.5	0.4	0.3
pH		8.47	8.80	8.82	8.84	8.85
饱和含水量/（cm³/cm³）		0.410 5	0.420 9	0.257 8	0.426 0	0.429 2
饱和导水率/（cm/d）		45.60	25.13	55.56	7.49	130.30

作物	模型	常规	扰动	极端
玉米	Baseline	990.10±144.55	997.60±142.00	600.67±524.62
	AgriAgent-1.5B	990.10±144.55	997.60±142.00	600.67±524.62
	AgriAgent-3B	5 440.80±1 520.62	5 287.33±1 471.01	3 304.53±2 950.12
	AgriAgent-7B	6 557.83±950.12	5 584.17±1 200.45	3 385.20±2 900.34
小米	Baseline	867.20±268.49	894.63±268.79	721.97±426.74
	AgriAgent-1.5B	867.20±268.49	894.63±268.79	721.97±426.74
	AgriAgent-3B	5 281.03±1 174.62	5 291.87±1 428.79	3 431.40±1 948.76
	AgriAgent-7B	6 474.03±1 400.56	5 892.70±1 200.78	3 257.83±1 800.45
甜菜	Baseline	8 587.90±6 250.11	8 853.70±6 459.85	8 845.07±7 099.96
	AgriAgent-1.5B	8 592.87±6 265.19	7 835.5±6 465.73	9 081.30±7 113.27
	AgriAgent-3B	16 755.30±5 911.93	13 818.70±6 247.26	15 365.40±7 188.85
	AgriAgent-7B	28 186.00±2 745.67	19 315.33±2 400.50	19 938.23±2 800.25
番茄	Baseline	39.43±57.93	35.20±135.13	22.13±91.36
	AgriAgent-1.5B	39.43±57.93	35.20±135.13	22.13±91.36
	AgriAgent-3B	367.97±178.01	352.67±142.79	300.03±194.80
	AgriAgent-7B	404.63±120.34	380.00±150.67	362.17±200.12
卷心菜	Baseline	88.87±6.52	84.97±7.32	35.20±25.99
	AgriAgent-1.5B	88.87±6.52	84.97±7.32	35.20±25.99
	AgriAgent-3B	398.53±127.86	336.60±158.31	311.57±142.41
	AgriAgent-7B	534.70±80.12	513.77±70.45	452.27±90.23

决策错误	天气条件	对产量的影响
极端高温下灌溉不足	温度>作物临界高温	作物热胁迫，光合作用受阻，直接减产
极端高温下大量施肥	温度>作物临界高温+5 ℃	烧苗，根系损伤，不可逆伤害
干旱条件灌溉不足	降水少+温度高	水分胁迫，生长停滞，严重减产
低湿度高温灌溉不足	湿度低+温度高	过度蒸腾，水分失衡，萎蔫死亡

决策错误	天气条件	对产量的影响
降水充足仍大量灌溉	降水>适宜范围上限	根系缺氧，病害滋生，中等减产
极端低温过量灌溉	温度<作物临界低温	冻害风险，生长延迟，可能减产
强降水大量施肥	降水>20 mm	肥料流失，浪费资源，轻度减产

决策错误	天气条件	对产量的影响
高湿度过量灌溉	湿度>85%	真菌病害风险，品质下降
大风高温灌溉不足	风速大+温度高	轻微水分胁迫，恢复较快
低辐射大量施肥	辐射<阈值	肥料利用率低，资源浪费