Mathematical Model and Optimal Control of New-Castle Disease (ND)

IF 4.6 2区数学 Q1 MATHEMATICS, APPLIED

Applied and Computational Mathematics Pub Date : 2020-06-05 DOI:10.11648/J.ACM.20200903.14

Uwakwe Joy Ijeoma, Inyama Simeon Chioma, O. Andrew

{"title":"Mathematical Model and Optimal Control of New-Castle Disease (ND)","authors":"Uwakwe Joy Ijeoma, Inyama Simeon Chioma, O. Andrew","doi":"10.11648/J.ACM.20200903.14","DOIUrl":null,"url":null,"abstract":"We formulated a five compartmental model of ND for both the ordinary and control models. We first determined the basic Reproduction number and the existence of Steady (Equilibrium) states (disease-free and endemic). Conditions for the local stability of the disease-free and endemic steady states were determined. Further, the Global stability of the disease-free equilibrium (DFE) and endemic equilibrium were proved using Lyponav method. We went further to carry out the sensitivity analysis or parametric dependence on R0 and later formulated the optimal control problem. We finally looked at numerical Results on poultry productivity in the presence of Infectious Newcastle Disease (ND) and we drew six graphs to demonstrate this. We observe that in absence of any control measure, the number of latently infected birds will increase rapidly from the initial population size of 80 to 160 birds within 1-3 days, whereas in the presence of control measures the population size will reduces to about 30 birds and goes to a stable state. This shows that the control measures are effective. The effect of the three control measures on the infectious classes can be seen. The number of non-productive infectious birds reduces to zero with control whereas the number of infectious productive reduces to about 8 birds and goes to its stable state when control is applied. This shows that the application of all three control measures tends to be more effective in the non- productive infectious bird population. It was also establish that the combination of efficient vaccination therapy and optimal efficacy of the vaccines are significantly more effective in the infectious productive birds’ population, since the combination reduces the population size of the birds to zero with 9–10 days. From the simulation also we see that optimal efficacy of the vaccine and effort to increase the number of recovered birds increases the number of latently infected birds population to about 129 at the early days of the infection whereas from another graph, the infectious productive birds reduces to 15 while the non -productive birds reduces to zero. The results from the simulation also show clearly, the effect of vaccination therapy on the latently infected birds. We observe that this programme will reduce the number of latently infected birds even if it not done more often. From the simulation, we further observe that this programme has effect on the infectious classes especially the non-productive infectious bird population, which reduces to zero after about 4 days.","PeriodicalId":55503,"journal":{"name":"Applied and Computational Mathematics","volume":"47 1","pages":"70"},"PeriodicalIF":4.6000,"publicationDate":"2020-06-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"12","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Applied and Computational Mathematics","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.11648/J.ACM.20200903.14","RegionNum":2,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATHEMATICS, APPLIED","Score":null,"Total":0}

引用次数: 12

Abstract

We formulated a five compartmental model of ND for both the ordinary and control models. We first determined the basic Reproduction number and the existence of Steady (Equilibrium) states (disease-free and endemic). Conditions for the local stability of the disease-free and endemic steady states were determined. Further, the Global stability of the disease-free equilibrium (DFE) and endemic equilibrium were proved using Lyponav method. We went further to carry out the sensitivity analysis or parametric dependence on R0 and later formulated the optimal control problem. We finally looked at numerical Results on poultry productivity in the presence of Infectious Newcastle Disease (ND) and we drew six graphs to demonstrate this. We observe that in absence of any control measure, the number of latently infected birds will increase rapidly from the initial population size of 80 to 160 birds within 1-3 days, whereas in the presence of control measures the population size will reduces to about 30 birds and goes to a stable state. This shows that the control measures are effective. The effect of the three control measures on the infectious classes can be seen. The number of non-productive infectious birds reduces to zero with control whereas the number of infectious productive reduces to about 8 birds and goes to its stable state when control is applied. This shows that the application of all three control measures tends to be more effective in the non- productive infectious bird population. It was also establish that the combination of efficient vaccination therapy and optimal efficacy of the vaccines are significantly more effective in the infectious productive birds’ population, since the combination reduces the population size of the birds to zero with 9–10 days. From the simulation also we see that optimal efficacy of the vaccine and effort to increase the number of recovered birds increases the number of latently infected birds population to about 129 at the early days of the infection whereas from another graph, the infectious productive birds reduces to 15 while the non -productive birds reduces to zero. The results from the simulation also show clearly, the effect of vaccination therapy on the latently infected birds. We observe that this programme will reduce the number of latently infected birds even if it not done more often. From the simulation, we further observe that this programme has effect on the infectious classes especially the non-productive infectious bird population, which reduces to zero after about 4 days.

查看原文本刊更多论文

新城病的数学模型及最优控制

我们为普通模型和控制模型都制定了ND的五室模型。我们首先确定了基本繁殖数和稳定(平衡)状态(无病和地方病)的存在。确定了无病和地方性稳定状态的局部稳定条件。此外，利用Lyponav方法证明了无病平衡(DFE)和地方性平衡的全局稳定性。我们进一步进行了灵敏度分析或参数对R0的依赖，并在此基础上制定了最优控制问题。我们最后研究了传染性新城疫(ND)下家禽生产力的数值结果，并绘制了六张图来证明这一点。我们观察到，在没有任何控制措施的情况下，潜伏感染的鸟类数量会在1-3天内从最初的80只迅速增加到160只，而在有控制措施的情况下，潜伏感染的鸟类数量会减少到30只左右，并趋于稳定。这说明控制措施是有效的。三种控制措施对感染类的效果可见一斑。非生产性传染性鸟类的数量在控制下减少到零，而传染性生产性鸟类的数量在控制下减少到约8只，并进入稳定状态。这表明，在非生产性传染性鸟类种群中，所有三种控制措施的应用往往更有效。研究还发现，有效的疫苗接种治疗和最佳的疫苗效果相结合，在具有传染性的生产性鸟类群体中更有效，因为这种组合在9-10天内将鸟类的种群规模减少到零。从模拟中我们还看到，疫苗的最佳功效和增加恢复鸟类数量的努力使潜伏感染鸟类的数量在感染早期增加到129只左右，而从另一张图中可以看出，具有传染性的生产性鸟类减少到15只，而非生产性鸟类减少到零。模拟结果也清楚地显示了疫苗治疗对潜伏感染的鸟类的效果。我们注意到，这一方案即使不经常实施，也将减少潜伏感染禽鸟的数量。通过模拟，我们进一步观察到该方案对感染类的影响，特别是对非生产性感染鸟种群的影响，在4天后减少到零。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Applied and Computational Mathematics 数学-应用数学

CiteScore

8.80

自引率

5.00%

发文量

审稿时长

6 months

期刊介绍： Applied and Computational Mathematics (ISSN Online: 2328-5613, ISSN Print: 2328-5605) is a prestigious journal that focuses on the field of applied and computational mathematics. It is driven by the computational revolution and places a strong emphasis on innovative applied mathematics with potential for real-world applicability and practicality. The journal caters to a broad audience of applied mathematicians and scientists who are interested in the advancement of mathematical principles and practical aspects of computational mathematics. Researchers from various disciplines can benefit from the diverse range of topics covered in ACM. To ensure the publication of high-quality content, all research articles undergo a rigorous peer review process. This process includes an initial screening by the editors and anonymous evaluation by expert reviewers. This guarantees that only the most valuable and accurate research is published in ACM.