Biological Computing From Microscopic to Macroscopic Evolution

Author

Xiaofeng Ding, Missouri University of Science and Technology

Abstract

A unified theory from microscopic to macroscopic DNA-based biological systems is explained in terms of the rule components used when the system size is increased. Even though the eight female rules in each ruleset are provided with an equal probability of the computation-state outcomes, the initial ensemble of the computation states will exponentially settle into one dominant rule that supports the nutrition needed for growth. The remaining seven rules form into two minority groups to provide the biological characteristics of the system's growth from a micro to macroscopic evolution. The object of this study is to prove that such a theory exists and is coherent within its boundaries. The proving process involves computing a simulation to compare and set groups between the results. From there, the difference between each computation result can be labeled and used to confirm that there is indeed a relationship between microscopic and macroscopic DNA-based biological systems.

Advisor(s)

Wu, Cheng-Hsiao

Committee Member(s)

Stanley, R. Joe
Swift, Theresa M.

Department(s)

Electrical and Computer Engineering

Degree Name

M.S. in Electrical and Computer Engineering

Publisher

Missouri University of Science and Technology

Publication Date

Fall 2025

Pagination

ix, 42 pages

Note about bibliography

Includes_bibliographical_references_(page 41)

Rights

© 2025 Xiaofeng Ding , All Rights Reserved

Document Type

Thesis - Open Access

File Type

text

Language

English

Thesis Number

T 12563

Recommended Citation

Ding, Xiaofeng, "Biological Computing From Microscopic to Macroscopic Evolution" (2025). Masters Theses. 8276.
https://scholarsmine.mst.edu/masters_theses/8276