An optimal control model for Coffee Berry Disease and Coffee Leaf Rust co-infection

Journal of Mathematical Analysis and Modeling Pub Date : 2024-03-19 DOI:10.48185/jmam.v5i1.944

H. Nyaberi, W. N. Mutuku, D. Malonza, G. Gachigua, G. Alworah

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Abstract

In the 1980s, coffee production in Kenya was peaking at an average of 1.7 million bags annually. Since then, this production has been declining to the current production of below 0.9 million bags annually. Coffee berry disease (CBD) and Coffee leaf rust (CLR) are some of the causes of this decline. This is due to a lack of sufficient knowledge on optimal control strategies for co-infection of CBD and CLR. In this research, we derive a system of ODEs from the mathematical model for co-infection of CBD and CLR with prevention of CBD infection, prevention of CLR infection, the treatment of CBD-infected coffee plants, the treatment of CLR-infected coffee plants, the treatment of CBD-CLR Co-infected coffee plants, elimination of Colletotrichum kahawae pathogens and elimination of Hemileia vastatrix pathogens to perform optimal control analysis. An optimal control problem is formulated andsolved using Pontryagin’s maximum principle. The outcomes of the model’s numerical simulations indicate that combining all controls would be the best strategy for slowing the spread of the CBD-CLR co-infection.

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咖啡浆果病和咖啡叶锈病共同感染的优化控制模型

20 世纪 80 年代，肯尼亚的咖啡产量达到顶峰，年均 170 万袋。从那时起，咖啡产量开始下降，目前年产量不足 90 万袋。咖啡浆果病（CBD）和咖啡叶锈病（CLR）是导致产量下降的部分原因。这是由于对 CBD 和 CLR 共同感染的最佳控制策略缺乏足够的了解。在这项研究中，我们从 CBD 和 CLR 共感染的数学模型中推导出一个 ODEs 系统，包括预防 CBD 感染、预防 CLR 感染、处理 CBD 感染的咖啡植株、处理 CLR 感染的咖啡植株、处理 CBD-CLR 共感染的咖啡植株、消除 Colletotrichum kahawae 病原体和消除 Hemileia vastatrix 病原体，从而进行最优控制分析。利用庞特里亚金最大原则提出并解决了最优控制问题。该模型的数值模拟结果表明，将所有控制措施结合起来是减缓 CBD-CLR 协同感染传播的最佳策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Mathematical Analysis and Modeling

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