A mathematical framework for the statistical interpretation of biological growth models

IF 2 4区 生物学 Q2 BIOLOGY
A. Samoletov, B. Vasiev
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引用次数: 0

Abstract

Biological entities are inherently dynamic. As such, various ecological disciplines use mathematical models to describe temporal evolution. Typically, growth curves are modelled as sigmoids, with the evolution modelled by ordinary differential equations. Among the various sigmoid models, the logistic, Gompertz and Richards equations are well-established and widely used for the purpose of fitting growth data in the fields of biology and ecology. The present paper puts forth a mathematical framework for the statistical analysis of population growth models. The analysis is based on a mathematical model of the population–environment relationship, the theoretical foundations of which are discussed in detail. By applying this theory, stochastic evolutionary equations are obtained, for which the logistic, Gompertz, Richards and Birch equations represent a limiting case. To substantiate the models of population growth dynamics, the results of numerical simulations are presented. It is demonstrated that a variety of population growth models can be addressed in a comparable manner. It is suggested that the discussed mathematical framework for statistical interpretation of the joint population–environment evolution represents a promising avenue for further research.
生物生长模型统计解释的数学框架。
生物实体本身就是动态的。因此,各种生态学科都使用数学模型来描述时间演化。通常情况下,生长曲线被建模为西格玛模型,其演化由常微分方程模拟。在各种 sigmoid 模型中,Logistic 方程、Gompertz 方程和 Richards 方程已被广泛应用于生物学和生态学领域的生长数据拟合。本文提出了人口增长模型统计分析的数学框架。分析以种群与环境关系的数学模型为基础,并详细讨论了该模型的理论基础。通过应用这一理论,可以得到随机演化方程,其中逻辑方程、贡珀茨方程、理查兹方程和桦树方程代表了极限情况。为了证实人口增长动力学模型,介绍了数值模拟的结果。结果表明,各种人口增长模型都能以类似的方式加以解决。我们认为,所讨论的对种群-环境联合演化进行统计解释的数学框架是一个很有前途的进一步研究途径。
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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来源期刊
Biosystems
Biosystems 生物-生物学
CiteScore
3.70
自引率
18.80%
发文量
129
审稿时长
34 days
期刊介绍: BioSystems encourages experimental, computational, and theoretical articles that link biology, evolutionary thinking, and the information processing sciences. The link areas form a circle that encompasses the fundamental nature of biological information processing, computational modeling of complex biological systems, evolutionary models of computation, the application of biological principles to the design of novel computing systems, and the use of biomolecular materials to synthesize artificial systems that capture essential principles of natural biological information processing.
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