{"title":"Dynamical analysis combined with parameter identification for a model of infection in honeybee colonies with social immunity","authors":"A. Atanasov, S. Georgiev, L. Vulkov","doi":"10.55630/j.biomath.2023.12.166","DOIUrl":null,"url":null,"abstract":"Several models on honeybee population dynamics have been considered in the past decades, which explain that the growth of beecolonies is highly dependent on the availability of food and social inhibition. The phenomenon of the Colony Collapse Disorder (CCD) and its exact causes remain unclear and here we are interested on the factor of social immunity.\nWe work with the mathematical model in [1]. The core model, consisting of four nonlinear ordinary differential equations with unknown functions: brood and nurses B, iB, N and iN represent the number of healthy brood, infected brood, healthy nurses, and infected nurses, respectively.\nFirst, this model implements social segregation. High-risk individuals such as foragers are limited to contact only nectar-receivers, but not other vulnerable individuals (nurses and brood) inside the nest. Secondly, it includes the hygienic behavior, by which healthy nurses actively remove infected workers and brood from the colony.\nWe aim to study the dynamics and the long-term behavior of the proposed model, as well as to discuss the effects of crucial parameters associated with the model. In the first stage, we study the model equilibria stability in dependence of the reproduction number.\nIn the second stage, we investigate the inverse problem of parameters identification in the model based on finite number time measurements of the population size. The conjugate gradient method with explicit Frechet derivative of the cost functional is proposed for the numerical solution of the inverse problem.\nComputational results with synthetic and realistic data are performed and discussed.","PeriodicalId":52247,"journal":{"name":"Biomath","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-04-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Biomath","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.55630/j.biomath.2023.12.166","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"Agricultural and Biological Sciences","Score":null,"Total":0}
引用次数: 0
Abstract
Several models on honeybee population dynamics have been considered in the past decades, which explain that the growth of beecolonies is highly dependent on the availability of food and social inhibition. The phenomenon of the Colony Collapse Disorder (CCD) and its exact causes remain unclear and here we are interested on the factor of social immunity.
We work with the mathematical model in [1]. The core model, consisting of four nonlinear ordinary differential equations with unknown functions: brood and nurses B, iB, N and iN represent the number of healthy brood, infected brood, healthy nurses, and infected nurses, respectively.
First, this model implements social segregation. High-risk individuals such as foragers are limited to contact only nectar-receivers, but not other vulnerable individuals (nurses and brood) inside the nest. Secondly, it includes the hygienic behavior, by which healthy nurses actively remove infected workers and brood from the colony.
We aim to study the dynamics and the long-term behavior of the proposed model, as well as to discuss the effects of crucial parameters associated with the model. In the first stage, we study the model equilibria stability in dependence of the reproduction number.
In the second stage, we investigate the inverse problem of parameters identification in the model based on finite number time measurements of the population size. The conjugate gradient method with explicit Frechet derivative of the cost functional is proposed for the numerical solution of the inverse problem.
Computational results with synthetic and realistic data are performed and discussed.
在过去的几十年中,人们已经研究了多个蜜蜂种群动态模型,这些模型解释了蜂群的增长在很大程度上取决于食物的供应和社会抑制。蜂群崩溃紊乱症(CCD)现象及其确切原因仍不清楚,在此,我们对社会免疫因素感兴趣。该核心模型由四个非线性常微分方程组成,其未知函数为:育雏器和哺乳器 B、iB、N 和 iN 分别代表健康育雏器、受感染育雏器、健康哺乳器和受感染哺乳器的数量。首先,该模型实现了社会隔离,高风险个体(如觅食者)只能接触花蜜接收者,而不能接触巢内其他易受感染的个体(哺育者和雏鸟)。其次,它还包括卫生行为,即健康的哺育者会主动将受感染的工蜂和雏蜂赶出蜂群。我们的目的是研究拟议模型的动态和长期行为,并讨论与模型相关的关键参数的影响。在第一阶段,我们研究了与繁殖数量相关的模型平衡稳定性。在第二阶段,我们研究了基于种群数量有限时间测量的模型参数识别逆问题。在逆问题的数值求解中,我们提出了带有成本函数显式弗雷谢特导数的共轭梯度法。