TY  - CHAP
AU  - Mitić, Vojislav
AU  - Lazović, Goran
AU  - Milošević, Dušan
AU  - Manojlović, Jelena
AU  - Ristanović, Elizabeta
AU  - Simeunović, Dragan
AU  - Tsay, Shwu-Chen
AU  - Milošević, Mimica
AU  - Soković, Marina
AU  - Vlahović, Branislav
PY  - 2023
UR  - https://link.springer.com/10.1007/978-3-031-17269-4_16
UR  - http://radar.ibiss.bg.ac.rs/handle/123456789/5401
AB  - One of the main motivations for our research was to find a connection between the Brownian motion of microorganisms within fractal nature, with the idea of developing an appropriate procedure and method to control the microorganism’s motion direction and predict the position of the microorganism in time. In this paper, we have followed the results of the very rear microorganism’s motion sub-microstructures in the experimental microstructure analysisFractals already observed and published. All of these data have been good basis to describe the motion trajectory by time interval method and fractals. We successfully defined the diagrams in two and three-dimensions and we were able to establish the control of Brownian chaotic motion as a bridge between chaotic disorders to control disorder. This significant study opens a new possibility for future investigation and the new potential of total control of the microorganism motion. These perspectives and findings provide significant data for getting more information from these bio systems. They can also be applied, based on self-similarities and biomimetics, to particle physical systemMatterFractalss and matter, generally.
PB  - Springer
T2  - Bioceramics, Biomimetic and Other Compatible Materials Features for Medical Applications
T1  - Brownian Motion Fractal Nature Frontiers Within the Matter
DO  - 10.1007/978-3-031-17269-4_16
SP  - 325
EP  - 343
ER  - 

@inbook{
editor = "Najman, Stevo, Mitić, Vojislav, Groth, Thomas, Barbeck, Mike, Chen, Po-Yu, Sun, Ziqi, Randjelović, Branislav",
author = "Mitić, Vojislav and Lazović, Goran and Milošević, Dušan and Manojlović, Jelena and Ristanović, Elizabeta and Simeunović, Dragan and Tsay, Shwu-Chen and Milošević, Mimica and Soković, Marina and Vlahović, Branislav",
year = "2023",
abstract = "One of the main motivations for our research was to find a connection between the Brownian motion of microorganisms within fractal nature, with the idea of developing an appropriate procedure and method to control the microorganism’s motion direction and predict the position of the microorganism in time. In this paper, we have followed the results of the very rear microorganism’s motion sub-microstructures in the experimental microstructure analysisFractals already observed and published. All of these data have been good basis to describe the motion trajectory by time interval method and fractals. We successfully defined the diagrams in two and three-dimensions and we were able to establish the control of Brownian chaotic motion as a bridge between chaotic disorders to control disorder. This significant study opens a new possibility for future investigation and the new potential of total control of the microorganism motion. These perspectives and findings provide significant data for getting more information from these bio systems. They can also be applied, based on self-similarities and biomimetics, to particle physical systemMatterFractalss and matter, generally.",
publisher = "Springer",
journal = "Bioceramics, Biomimetic and Other Compatible Materials Features for Medical Applications",
booktitle = "Brownian Motion Fractal Nature Frontiers Within the Matter",
doi = "10.1007/978-3-031-17269-4_16",
pages = "325-343"
}

Najman, S., Mitić, V., Groth, T., Barbeck, M., Chen, P., Sun, Z., Randjelović, B., Mitić, V., Lazović, G., Milošević, D., Manojlović, J., Ristanović, E., Simeunović, D., Tsay, S., Milošević, M., Soković, M.,& Vlahović, B.. (2023). Brownian Motion Fractal Nature Frontiers Within the Matter. in Bioceramics, Biomimetic and Other Compatible Materials Features for Medical Applications
Springer., 325-343.
https://doi.org/10.1007/978-3-031-17269-4_16

Najman S, Mitić V, Groth T, Barbeck M, Chen P, Sun Z, Randjelović B, Mitić V, Lazović G, Milošević D, Manojlović J, Ristanović E, Simeunović D, Tsay S, Milošević M, Soković M, Vlahović B. Brownian Motion Fractal Nature Frontiers Within the Matter. in Bioceramics, Biomimetic and Other Compatible Materials Features for Medical Applications. 2023;:325-343.
doi:10.1007/978-3-031-17269-4_16 .

Najman, Stevo, Mitić, Vojislav, Groth, Thomas, Barbeck, Mike, Chen, Po-Yu, Sun, Ziqi, Randjelović, Branislav, Mitić, Vojislav, Lazović, Goran, Milošević, Dušan, Manojlović, Jelena, Ristanović, Elizabeta, Simeunović, Dragan, Tsay, Shwu-Chen, Milošević, Mimica, Soković, Marina, Vlahović, Branislav, "Brownian Motion Fractal Nature Frontiers Within the Matter" in Bioceramics, Biomimetic and Other Compatible Materials Features for Medical Applications (2023):325-343,
https://doi.org/10.1007/978-3-031-17269-4_16 . .

TY  - JOUR
AU  - Aleksić, Sanja
AU  - Marković, Bojana
AU  - Mitić, Vojislav V.
AU  - Milošević, Dušan
AU  - Milošević, Mimica
AU  - Soković, Marina
AU  - Vlahović, Branislav
PY  - 2021
UR  - https://www.worldscientific.com/doi/abs/10.1142/S0218126622500748
UR  - https://radar.ibiss.bg.ac.rs/handle/123456789/4636
AB  - Biophysical and condensed matter systems connection is of great importance nowadays due to the need for a new approach in microelectronic biodevices, biocomputers or biochips advanced development. Considering that the living and nonliving systems’ submicroparticles are identical, we can establish the biunivocally correspondent relation between these two particle systems, as a biomimetic correlation based on Brownian motion fractal nature similarities, as the integrative property. In our research, we used the experimental results of bacterial motion under the influence of energetic impulses, like music, and also some biomolecule motion data. Our goal is to define the relation between biophysical and physical particle systems, by introducing mathematical analytical forms and applying Brownian motion fractal nature characterization and fractal interpolation. This work is an advanced research in the field of new solutions for high-level microelectronic integrations, which include submicrobiosystems like part of even organic microelectronic considerations, together with some physical systems of particles in solid-state solutions as a nonorganic part. Our research is based on Brownian motion minimal joint properties within the integrated biophysical systems in the wholeness of nature.
PB  - World Scientific Publishing Company
T2  - Journal of Circuits, Systems and Computers
T1  - Interpolation Methods Applied on Biomolecules and Condensed Matter Brownian Motion
DO  - 10.1142/s0218126622500748
ER  - 

@article{
author = "Aleksić, Sanja and Marković, Bojana and Mitić, Vojislav V. and Milošević, Dušan and Milošević, Mimica and Soković, Marina and Vlahović, Branislav",
year = "2021",
abstract = "Biophysical and condensed matter systems connection is of great importance nowadays due to the need for a new approach in microelectronic biodevices, biocomputers or biochips advanced development. Considering that the living and nonliving systems’ submicroparticles are identical, we can establish the biunivocally correspondent relation between these two particle systems, as a biomimetic correlation based on Brownian motion fractal nature similarities, as the integrative property. In our research, we used the experimental results of bacterial motion under the influence of energetic impulses, like music, and also some biomolecule motion data. Our goal is to define the relation between biophysical and physical particle systems, by introducing mathematical analytical forms and applying Brownian motion fractal nature characterization and fractal interpolation. This work is an advanced research in the field of new solutions for high-level microelectronic integrations, which include submicrobiosystems like part of even organic microelectronic considerations, together with some physical systems of particles in solid-state solutions as a nonorganic part. Our research is based on Brownian motion minimal joint properties within the integrated biophysical systems in the wholeness of nature.",
publisher = "World Scientific Publishing Company",
journal = "Journal of Circuits, Systems and Computers",
title = "Interpolation Methods Applied on Biomolecules and Condensed Matter Brownian Motion",
doi = "10.1142/s0218126622500748"
}

Aleksić, S., Marković, B., Mitić, V. V., Milošević, D., Milošević, M., Soković, M.,& Vlahović, B.. (2021). Interpolation Methods Applied on Biomolecules and Condensed Matter Brownian Motion. in Journal of Circuits, Systems and Computers
World Scientific Publishing Company..
https://doi.org/10.1142/s0218126622500748

Aleksić S, Marković B, Mitić VV, Milošević D, Milošević M, Soković M, Vlahović B. Interpolation Methods Applied on Biomolecules and Condensed Matter Brownian Motion. in Journal of Circuits, Systems and Computers. 2021;.
doi:10.1142/s0218126622500748 .

Aleksić, Sanja, Marković, Bojana, Mitić, Vojislav V., Milošević, Dušan, Milošević, Mimica, Soković, Marina, Vlahović, Branislav, "Interpolation Methods Applied on Biomolecules and Condensed Matter Brownian Motion" in Journal of Circuits, Systems and Computers (2021),
https://doi.org/10.1142/s0218126622500748 . .