生物物理系统中快速崩溃和毁灭性入侵爆发的阈值效应建模

IF 0.8 4区 物理与天体物理 Q4 PHYSICS, APPLIED
A. Yu. Perevaryukha
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引用次数: 0

摘要

针对特殊危机案例开发了一种混合计算建模方法。探讨了各种生物物理系统中突然出现的极端现象和瞬态过程。数学生物物理学方法需要灵活扩展,以适应情境激活的强烈影响因素,这一点在 COVID-19 大流行病中得到了很好的证明,病毒的超级传播和新 COVID 波的瞬间启动都产生了影响。本文比较了几个具有重要经济意义且难以预测的极端生物物理过程,这些过程的演化阶段变化非常快。快速入侵爆发是破坏生物物理系统功能现象的一个典型例子。入侵过程的各个阶段在很短的时间间隔内就超越了进化过程中既定的调控原则框架,因此会产生破坏性影响。根据生物控制论的反馈原理,在快速爆发阶段之后,入侵者及其生物物理环境都会面临严重的危机。当地人口可能死亡。其他突发性危机则是由影响对经济有价值的种群的不正确调节算法引发的。在本研究中,我们开发了一种之前讨论过的基于微分方程组织混合计算结构的方法。通过计算辅助生物物理指标,确定重新定义的时刻,从而改变研究过程的阶段,从而找到方程形式的转换事件。介绍了混合结构的高级版本和崩溃效应的模型方案。证明了专家调节对生物物理系统影响的非线性动态估计的逻辑错误。使用一组替代谓词,对违反生物物理平衡的危险外来入侵者的种群爆发进行了模拟分析。在外来物种活跃入侵破坏环境资源(如加拿大的莱曼特里亚虫入侵)之前,该情景分析可确定控制外来物种的措施在哪些入侵阶段是有效的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Modeling Threshold Effects of Rapid Collapse and Devastating Invasion Outbreaks in Biophysical Systems

Modeling Threshold Effects of Rapid Collapse and Devastating Invasion Outbreaks in Biophysical Systems

Modeling Threshold Effects of Rapid Collapse and Devastating Invasion Outbreaks in Biophysical Systems

A methodology for hybrid computational modeling for special crisis cases is developed. Extreme phenomena and transient processes occurring suddenly in various biophysical systems are explored. The methods of mathematical biophysics require flexible expansion due to situationally activated intense influencing factors, which has been demonstrated well by the COVID-19 pandemic with the effects of virus superspreading and the instant launch of new COVID waves. Several economically important and hard-to-predict extreme biophysical processes with very rapidly changing evolutionary stages are compared. A classic example of a phenomenon disrupting the functioning of a biophysical system is a rapid invasion outbreak. Stages of the invasion process pass beyond the framework of the evolutionarily established regulatory principles in a short time interval and, therefore, can have a devastating effect. The feedback principle in biocybernetics leads to a scenario in which the rapid outbreak stage is followed by the effect of a deep crisis, both for an aggressive invader and its biophysical environment. A local population can die. Other sudden crises are provoked by an incorrectly regulated algorithm for influencing populations that are valuable for the economy. In this study, a previously discussed method for organizing hybrid computational structures on the basis of differential equations is developed. The events of switching the forms of equations are found by calculating auxiliary biophysical indicators that specify the moments of redefinitions for changing the stages of the investigated process. An advanced version of a hybrid structure and model scenarios for the collapse effect are presented. Logical errors in estimating the nonlinear dynamics with expert regulation of the impact on a biophysical system are demonstrated. Using an alternative set of predicates, a simulation analysis of launching an invasive outbreak of the population for a dangerous alien invader violating biophysical equilibrium is carried out. The scenario singles out the invasion stages at which measures for controlling an alien species are efficient before an active invader destroyed the environmental resources like Lymantria dispar invasion in Canada.

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来源期刊
Technical Physics Letters
Technical Physics Letters 物理-物理:应用
CiteScore
1.50
自引率
0.00%
发文量
44
审稿时长
2-4 weeks
期刊介绍: Technical Physics Letters is a companion journal to Technical Physics and offers rapid publication of developments in theoretical and experimental physics with potential technological applications. Recent emphasis has included many papers on gas lasers and on lasing in semiconductors, as well as many reports on high Tc superconductivity. The excellent coverage of plasma physics seen in the parent journal, Technical Physics, is also present here with quick communication of developments in theoretical and experimental work in all fields with probable technical applications. Topics covered are basic and applied physics; plasma physics; solid state physics; physical electronics; accelerators; microwave electron devices; holography.
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