Optimization of resource allocation, exposure time and rotary speed of incubative eggs

• Autorzy: Milenin Dmytro , Lysychenko Mykola , Milenin Andriy , Koval Leonid , Amirgaliyeva Saltanat , Satymbekov Maxatbek , Adikanova Saltanat

Identyfikatory

DOI

10.35784/iapgos.3494

Warianty tytułu

PL

Optymalizacja alokacji zasobów, czasu ekspozycji i prędkości obrotowej jaj inkubacyjnych

• Języki publikacji: EN

Abstrakty

EN

Recently, the laser technology of influencing biological objects in biology, medicine, and veterinary medicine has become widespread in order to activate certain biochemical and physiological processes in the organism. Any influence of electromagnetic radiation (in particular optical emission) requires the exact adherence to the recommended illumination dose to obtain a positive effect on the biological object. The article presents the results of a theoretical study concerning provision of uniform illumination of the egg’s surface, taking into account the location of the laser radiation source and rotating time of the egg.

PL

Ostatnio technologia laserowego oddziaływania na obiekty biologiczne w biologii, medycynie i weterynarii stała się powszechna w celu aktywacji pewnych procesów biochemicznych i fizjologicznych w organizmie. Każdy wpływ promieniowania elektromagnetycznego (w szczególności emisji optycznej) wymaga dokładnego przestrzegania zalecanej dawki oświetlenia w celu uzyskania pozytywnego wpływu na obiekt biologiczny. W artykule przedstawiono wyniki badań teoretycznych dotyczących zapewnienia równomiernego oświetlenia powierzchni jaja, biorąc pod uwagę lokalizację źródła promieniowania laserowego i czas obrotu jaja.

Słowa kluczowe

EN

laser emission; radiation dose; incubating egg

PL

emisja laserowa; dawka promieniowania; inkubowane jajo

• Wydawca: Wydawnictwo Politechniki Lubelskiej
• Czasopismo: Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska
• Rocznik: 2023
• Tom: T. 13, nr 2
• Strony: 15--19
• Opis fizyczny: Bibliogr. 27 poz., wykr.

Twórcy

autor

Milenin Dmytro

• State Biotechnological University, Kharkiv, Ukraine

• https://orcid.org/0000-0003-3058-2243

autor

Lysychenko Mykola

• State Biotechnological University, Kharkiv, Ukraine

• https://orcid.org/0000-0003-1611-6705

autor

Milenin Andriy

• State Biotechnological University, Kharkiv, Ukraine

• https://orcid.org/0000-0003-3521-1652

autor

Koval Leonid

• Vinnytsia National Technical University, Vinnytsia, Ukraine

• https://orcid.org/0000-0001-9887-2605

autor

Amirgaliyeva Saltanat

• Academy of Logistics and Transport, Almaty, Kazakhstan

• https://orcid.org/0000-0001-5311-7227

autor

Satymbekov Maxatbek

• Al-Farabi Kazakh National University, Almaty, Kazakhstan

• https://orcid.org/0000-0002-4621-6646

autor

Adikanova Saltanat

• Sarsen Amanzholov East Kazakhstan University, Ust-Kamenogorsk, Kazakhstan

• https://orcid.org/0000-0003-0085-8384

Bibliografia

• [1] Avila R. E. et al. : Effects of He-Ne Laser Irradiation on Chicr Embryo Mesonephros. Journal of Clinical Lastr Vtdicint Sergery 10(4), 1992, 287–290.
• [2] Avrunin O. G. et al.: Application of 3D printing technologies in building patient-specific training systems for computing planning in rhinology. Information Technology in Medical Diagnostics II. CRC Press 2019, 1–8.
• [3] Dubolazov O. V. et al.: Laser Müller matrix diagnostics of changes in the optical anisotropy of biological tissues. Information Technology in Medical Diagnostics II. CRC Press 2019, 195–203.
• [4] Dubolazov O. V., Ushenko A. G.: The complex degree of coherence of the laser images of blood plasma and the diagnostics of oncological changes of human tissues. Information Technology in Medical Diagnostics II. CRC Press, Balkema book, Taylor & Francis Group, London, UK, 2019, 185–194.
• [5] Grossman N. et al.: 780 nm low power dide laser irradiation stimulates proliferation of kerationocyte cultures: invoivement of reactive oxygen species. Lastr Surg. Med. 22(4), 1998, 212–218.
• [6] Kholin V. V., Gamaleia N. F. et al.: Photodynamic therapy with laser scanning mode of tumor irradiation. Proc. SPIE 9816, 2015, 98161F.
• [7] Kondratiuk S. et al.: Information technology for security system based on cross platform software. NATO Science for Peace and Security Series A: Chemistry and Biology, 2018, 331–339.
• [8] Kondratiu S., Krak I.: Dactyl Alphabet Modeling and Recognition Using Cross Platform Software. 2nd International Conference on Data Stream Mining and Processing – DSMP, 2018, 8478417, 420–423.
• [9] Kozlovska T. I., Pavlov S. V.: Optoelectronic Means of Diagnosing Human Pathologies Associated with Peripheral Blood Circulation. LAP LAMBERT Academic Publishing, Beau Bassin 2019.
• [10] Krak I. V. et al.: Applied aspects of the synthesis and analysis of voice information. Cybernetics and Systems Analysis 49(4), 2013, 589–596.
• [11] Krak I., Kondratiuk S.: Cross-platform software for the development of sign communication system: Dactyl language modelling. 12th International Scientific and Technical Conference on Computer Sciences and Information Technologies – CSIT, 2017, 8098760, 167–170.
• [12] Kryvonos I. G. et al.: Predictive Text Typing System for the Ukrainian Language. Cybernetics and Systems Analysis 53(4), 2017, 495–502.
• [13] Kvyetnyy R. et al.: Method of image texture segmentation using Laws' energy measures. Proc. SPIE 10445, 2017, 1044561.
• [14] Kvyetnyy R. et al.: Modification of fractal coding algorithm by a combination of modern technologies and parallel computations. Proc. SPIE 9816, 2015, 98161R.
• [15] Kvyetnyy R. et al.: Blur recognition using second fundamental form of image surface. Proc. SPIE 9816, 2015, 98161A.
• [16] Kukharchuk V. V. et al.: Information Conversion in Measuring Channels with Optoelectronic Sensors. Sensors 22(1), 2022, 271 [http://doi.org/10.3390/s22010271].
• [17] Milenin D., Lysychenko M., Pankova O. et al.: Research of the ellipsoid area geometry illuminated by a point laser source., Optical Fibers and Their Applications. Proc. SPIE 11456, 2020, 114560M.
• [18] Milenin D. M., Lysychenko M. L.: Efektyvnist’lazernoyi obrobky inkubatsiynykh yayets’. Visnyk KHNTUSH 129, 2012, 84–87.
• [19] Milenin D., Lysychenko M.: Irradiation conditions still ellipsoid point sources. Pratsi TDAU 15, Т.2, 2015, 266–273.
• [20] Pavlov S. V. et al.: Methods and computer tools for identifying diabetes-induced fundus pathology. Information Technology in Medical Diagnostics II. CRC Press, Balkema book, 2019, 87–99.
• [21] Povoroznjuk A. et al.: Minimization risk doctor-mistake when designing computer decision support system in medicine. 13th International Conference: The Experience of Designing and Application of CAD Systems in Microelectronics – CADSM, 2015.
• [22] Rovira R., Tuzhanskyy S.: Polarimetric characterisation of histological section of skin with pathological changes. Proc. SPIE 10031, 2016, 100313E.
• [23] Samar M. E. et al.: Histological Changes Produced by He-Ne Laser on Diferent Tissues from Chick Embryo. Journal of Clinical Laser Medicine & Surgery 11(2), 1993, 87–89.
• [24] Selivanova K.G. et al.: Virtual training system for tremor prevention. Information Technology in Medical Diagnostics II. CRC Press, Balkema book, 2019, 9–14.
• [25] Wójcik W., Pavlov S.: Highly linear Microelectronic Sensors Signal Converters Based on Push-Pull Amplifier Circuits. Komitet Inżynierii Środowiska PAN, 181, Lublin 2022.
• [26] Wójcik W. et al.: Information Technology in Medical Diagnostics II. CRC Press, Balkema book, 2019.
• [27] Zhemchuzhkina T. V. et al.: Some technical propositions for electromyographical human interface device. Information Technology in Medical Diagnostics II. CRC Press, 2019, 15–21.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).