Analysis of Periodic Solution of DNA Catalytic Reaction Model With Random Disturbance

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2021-11-23 DOI:10.1109/OJNANO.2021.3130043
Hui Lv;Huiwen Li;Qiang Zhang
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引用次数: 2

Abstract

The realization of molecular logic circuit is inseparable from the design and analysis of catalytic reaction chain, and the DNA catalytic gate plays an important role in it. Discuss the nature of the solution to DNA catalytic reaction system, using Khasminskii's periodicity and Lyapunov analysis methods to obtain the existence of non-trivial positive periodic solutions of the system, and the solution is globally attractive. The existence of the solution indicates that according to the mathematical model established by the DNA catalytic reaction system, the system may reach the expected concentration value of an ideal state and obtain better reaction data, which provides a theoretical basis for the realization of the DNA catalytic gate function. Numerical simulation results show that under the influence of random disturbance and periodic parameters, the solution to the random DNA catalytic reaction system exists and is globally attractive, which also reflects that the DNA catalytic reaction system can reach an ideal reaction state. The solution to the DNA catalytic system with random disturbance will converge on a certain value and oscillate periodically between the solution to the deterministic system.
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随机扰动下DNA催化反应模型的周期解分析
分子逻辑电路的实现离不开催化反应链的设计和分析,而DNA催化门在其中起着重要的作用。讨论了DNA催化反应体系解的性质,利用Khasminskii的周期性和Lyapunov分析方法,得到了该体系非平凡正周期解的存在性,且解具有全局吸引力。该解的存在表明,根据DNA催化反应体系建立的数学模型,体系可以达到理想状态下的预期浓化值,获得较好的反应数据,为DNA催化门功能的实现提供了理论依据。数值模拟结果表明,在随机扰动和周期参数的影响下,随机DNA催化反应体系的解存在且具有全局吸引力,这也反映了DNA催化反应体系能够达到理想的反应状态。具有随机扰动的DNA催化系统的解将收敛于某一值,并在确定性系统的解之间周期性振荡。
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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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