Md. Abdul Latif Sarker
A black hole-aided deep-helix channel model for DNA. [Preprint]
Sarker, Md. Abdul Latif; Kader, Md. Fazlul; Sarker, Md. Mostafa Kamal; Lee, Moon Ho; Han, Dong Seog
Authors
Md. Fazlul Kader
Md. Mostafa Kamal Sarker
Moon Ho Lee
Dong Seog Han
Abstract
In this article, we present a black-hole-aided deep-helix (bh-dh) channel model to enhance information bound and mitigate a multiple-helix directional issue in Deoxyribonucleic acid (DNA) communications. The recent observations of DNA do not match with Shannon bound due to their multiple-helix directional issue. Hence, we propose a bh-dh channel model in this paper. The proposed bh-dh channel model follows a similar fashion of DNA and enriches the earlier DNA observations as well as achieving a composite like information bound. To do successfully the proposed bh-dh channel model, we first define a black-hole-aided Bernoulli-process and then consider a symmetric bh-dh channel model. After that, the geometric and graphical insight shows the resemblance of the proposed bh-dh channel model in DNA and Galaxy layout. In our exploration, the proposed bh-dh symmetric channel geometrically sketches a deep-pair-ellipse when a deep-pair information bit or digit is distributed in the proposed channel. Furthermore, the proposed channel graphically shapes as a beautiful circulant ring. The ring contains a central-hole, which looks like a central-black-hole of a Galaxy. The coordinates of the inner-ellipses denote a deep-double helix, and the coordinates of the outer-ellipses sketch a deep-parallel strand. Finally, the proposed bh-dh symmetric channel significantly outperforms the traditional binary-symmetric channel and is verified by computer simulations in terms of Shannon entropy and capacity bound.
Citation
SARKER, M.A.L., KADER, M.F., SARKER, M.M.K., LEE, M.H. and HAN, D.S. 2022. A black hole-aided deep-helix channel model for DNA. Research square [online], 10 January 2022, Preprint (version 3). Available from: https://doi.org/10.21203/rs.3.rs-1026992/v3
Working Paper Type | Preprint |
---|---|
Publicly Available Date | Jan 21, 2022 |
DOI | https://doi.org/10.21203/rs.3.rs-1026992/v3 |
Keywords | Black hole; Black-hole-aided Bernoulli-process; Deoxyribonucleic acid (DNA); Deep-helix; Deep-pair-ellipse; Beautiful-circulant-ring; Central-black-hole; Deep-double helix; Deep-parallel strand; Composite like information bound |
Public URL | https://rgu-repository.worktribe.com/output/1538529 |
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Copyright Statement
This preprint is under consideration at Scientific Reports. A preprint is a preliminary version of a manuscript that has not completed peer review at a journal. Research Square does not conduct peer review prior to posting preprints. The posting of a preprint on this server should not be interpreted as an endorsement of its validity or suitability for dissemination as established information or for guiding clinical practice.
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