Research on the Optimization of Crop Planting Strategies Based on a Multi-Factor Comprehensive Analysis Model

Honglin Hui; Hao Gong; Jiawen Gao; Xiuye Hu; Shaowen Wang

doi:10.62051/qfst4t37

Authors

Honglin Hui
Hao Gong
Jiawen Gao
Xiuye Hu
Shaowen Wang

DOI:

https://doi.org/10.62051/qfst4t37

Keywords:

Crop Planting Strategies; Linear Programming; Monte Carlo Simulation; Greedy Algorithm.

Abstract

This paper examines crop planting strategies from 2024 to 2030 in a rural village in the mountainous areas of North China to address the challenges posed by climate change and market volatility. Due to its special geographical location and climatic conditions, crop cultivation in the mountainous areas of North China is susceptible to drought and water shortage, which puts forward higher requirements for the optimization of planting strategies. The study considers two market scenarios: Scenario 1 assumes that the excess crop is completely unsalable, and Scenario 2 considers the excess crop being sold at half price. By simulating market fluctuations through the Monte Carlo algorithm and finding the optimal planting combination combined with the greedy algorithm, this paper seeks the optimal planting plan under different market conditions to maximize the net return. The results show that the optimization strategy can significantly improve the net income of crop planting, reduce the risk caused by market fluctuations, and help promote the sustainable development of rural economy. These optimization strategies have important theoretical and practical significance for improving the economic benefits of crop planting, enhancing the ability of agriculture to resist risks, and promoting the sustainable development of rural economy. Analyzing and optimizing crop planting strategies through scientific methods can not only ensure food security, but also promote agricultural modernization and achieve harmonious development of agriculture and the environment.

Downloads

Download data is not yet available.

References

[1] Lin Jiaorong, Wang Minghan, Zhang Liang. The Impact of Climate Warming on Crop Planting [J]. Rural Practical Technology, 2020, (08): 169-170.

[2] Hua Dongwen, Wang Jian. A Review of the Causes and Effects of Global Climate Change [J]. Regional Governance, 2020, (03): 138-140.

[3] Li Yanbin, Ma Jiatong, Li Daoxi, et al. Application of Improved Particle Swarm Algorithm in Agricultural Planting Structure Optimization [J]. Journal of Irrigation and Drainage, 2022, 41 (1):10.

[4] Zhang Lili. Application of Optimization Algorithms in Hyperspectral Detection Models for Crops [J]. New Agriculture, 2022 (000-013).

[5] Jia Yinjian, Zhang Huaijing, Lan Hao, et al. A Crop Classification Method, Device, and Computer Equipment Based on Improved Random Forest Algorithm: CN202210276403.3 [P]. CN202210276403.3 [2024-09-19].

[6] Zhu Peihua, Chen Lin. Estimation of Industrial Value Added and Total Factor Productivity—Based on a Pseudo-Monte Carlo Experiment of China's Manufacturing Industry [J]. China Industrial Economy, 2020, (07): 24-42.

[7] Zeng Xiaolin, Li Fanshi, Zhong Zhipei, et al. Decision-making problem of airport taxi drivers based on queuing theory and Monte Carlo algorithm [J]. Electronic Testing, 2020, (14): 51-52+114.

[8] Hao Liya. Research on Bayesian stochastic volatility model based on Monte Carlo simulation and its applications [D]. Hunan University, 2011.

[9] Zeng Ni, Chen Junhao, Fu Qingshuang. Dynamic programming strategy based on greedy algorithm [J]. Computer Knowledge and Technology, 2021, 17 (20): 141-143+152.

[10] Chen Yuheng, Chen Jinchao, Chen Xuecong. Cooperative task allocation of drone swarms based on improved greedy algorithm [J]. Aerospace Science and Technology, 2022, 33 (04): 13-18.