Safety, Risk, Reliability and Quality, Statistics, Probability and Uncertainty, Information Systems, Multidisciplinary
19
Scopus Publications
413
Scholar Citations
10
Scholar h-index
11
Scholar i10-index
Scopus Publications
Adaptive security: Strategic principles for complex socio-technical systems Fedir Korobeynikov, Volodymyr Mokhor Royal Society Open Science, 2026 Contemporary political and strategic challenges expose the limitations of the traditional security paradigm in socio-technical systems, which focuses on threat prediction, resistance to change and restoration to prior states. This article offers a conceptual perspective on adaptive security in complex socio-technical systems. It introduces the concept of transmorphance—the ability of complex systems to undergo directed architectural transformation while preserving core functions and systemic identity. Building on an interdisciplinary analysis of adaptation in complex systems, it proposes a conceptual model of adaptive security applicable to a wide range of socio-technical contexts. The framework comprises six strategic components aimed at systematically enhancing adaptive potential: entropy management, stimulation of evolutionary dynamics, resource base expansion, development of transformation capabilities, strengthening of self-governance and optimization of inter-systemic integration. Unlike traditional security models oriented towards recovery, transmorphance enables systems to evolve proactively under conditions of instability and uncertainty. The framework offers practical applicability across governance levels—from strategic responses to hybrid threats within the sphere of national security to the long-term resilience planning of local communities facing high-impact stochastic disruptions. The findings offer a scientific foundation for designing systems capable of leveraging uncertainty as a driver of directed evolution in turbulent environments.
Justifying Investment in Information Security: An Interpretation of the Black–Scholes Formula V. Zuyok, O. Kostenevych, O. Milenin, O. Makhnenko, M. Tretyakov, V. Hrudnytskyi, S. Lytovchenko Nuclear and Radiation Safety, 2026 An analysis of available data on the conditions for the initiation of delayed hydride cracking (DHC) as one of the mechanisms that can cause integrity loss of fuel zirconium cladding under dry storage conditions was performed. Based on the available experimental values for different zirconium alloy grades, a recommendation was made to use 5.0±2,5 MPa·m1/2 as a conservative critical value for the stress intensity factor in the vicinity of a crack, whose exceeding may result in DHC.Stresses arising in the fuel cladding can be caused by mechanical interaction between the fuel pellet and the cladding, pressure created by gaseous fission products (GFPs) under the cladding, and residual stresses in the weld joint zone. In the implementation of the dry storage technology, the maximum reduction in the radial gap between the fuel pellet and the cladding does not exceed 2.2 μm (for E110 cladding at a GFP pressure of 2.85 MPa), which is less than the minimum initial gap typical for irradiated fuel rods (15 μm). Therefore, it was concluded that the formation/growth of stresses in the fuel cladding, which could cause DHC initiation due to mechanical contact between the fuel pellet and the cladding, can be disregarded.Using the VERLIFE methodology, the stress intensity factor (KI) was calculated for the maximum permissible size (depth) of a postulated internal crack in the nuclear power industry, which is 0.25 of its thickness. This size is greater than the maximum fretting wear (10%) of the fuel cladding and is therefore more conservative.The set of calculations enabled to conclude that under thermal impact in the implementation of the dry storage technology, which includes vacuum drying followed by filling the Multi-Purpose Canister (MPC) with helium until a steady state is reached at a temperature of 350 °C, and during long-term storage of spent nuclear fuel (SNF) in the Ventilated Concrete Casks (VCCs) at the Dry Spent Fuel Storage Facility (DSFSF) site under normal conditions, due to the internal pressure under the cladding (GFPs, pellet), DHC will not be initiated, since the maximum calculated KI value for rods with E110 and ZIRLO alloy claddings is 1.81 MPa·m1/2, which is typical for ZIRLO alloy cladding at the vacuum drying stage (436 °C) and does not exceed the conservative critical value KIC = 5.0±2,5 MPa·m1/2.
Next-Level Electric Power Intelligence: Ensuring Resilience at the Tactical Level Volodymyr Mokhor, Andrii Davydiuk Proceedings 2024 14th International Conference on Dependable Systems Services and Technologies Trustworthy AI Internet of Robotics and Big Data for A Safe and Secure World Dessert 2024, 2024 Since 2014, Russia has launched extensive cyber and kinetic attacks on Ukraine's energy infrastructure. These efforts are designed not only to apply psychological pressure on the population but also to inflict significant material damage on the country's economy by causing cascading effects across multiple sectors. Additionally, they aim to influence nations that rely on energy exports from Ukraine. In 2024, Ukraine gained the capability to strike the fuel and energy complex of its adversary, which similarly impacts these critical factors. Notably, the success of any such operation depends on high-quality intelligence, including assessing potential effects and identifying vulnerabilities.This article examines research focused on energy intelligence and defines the concept as the systematic process of gathering and analyzing information on countries' energy resources, markets, policies, and technologies. This process enables the evaluation of economic and security impacts on a global or strategic scale. The goal of the research is to develop a method for the structural identification of military targets based on energy consumption, emphasizing the need for robust cybersecurity measures. This approach aims to enhance the accuracy of target detection and informs future research directions in the field of military energy intelligence at the same time based on energy consumption analysis, aiming to enhance energy efficiency, resilience, and security, and reduce operational costs. The article outlines the key objectives of energy intelligence, which include systematically collecting and analyzing data on energy resources, markets, and policies to understand their influence on business decisions, economic conditions, and security considerations through in-depth analysis of energy trends and geopolitical risks.The article explores the concept of next-generation electric power intelligence, focusing on enhancing resilience at the tactical level. It provides a classification of energy intelligence and identifies its main types. The discussion extends to various intelligence-gathering methods, including SIGINT, IMINT, OSINT, HUMINT, and EXIMINT, which are employed to collect and analyze data on energy systems and resources. Special attention is given to military energy intelligence, underlining its critical role in armed conflicts. A significant contribution of the article is the development of a method for the structural identification of military targets based on energy consumption patterns, aimed at improving tactical resilience and precision in modern combat situations. Overall, the article underscores the importance of an integrated approach and the involvement of various stakeholders to enhance the effectiveness of next-level electric power intelligence.
Guest Editorial Column: Special Issue of Journal of Mobile Multimedia “Artificial Intelligence in Automation with Mobile Applications” Journal of Mobile Multimedia, 2023
Model-Based Information Security Management Systems Architecture Ceur Workshop Proceedings, 2023
Cybersecurity Risk Assessment of Information Systems of Critical Infrastructure Objects Volodymyr Mokhor, Serhii Honchar, Alla Onyskova 2020 IEEE International Conference on Problems of Infocommunications Science and Technology Pic S and T 2020 Proceedings, 2021 The concept of complex cybersecurity risk of information systems of critical infrastructure objects is substantiated in the paper, the vector model of risk and model of complex risk is offered, the method of calculation of total risk, complex risk is offered, the structural decision of computer system for calculation of cybersecurity risk of information systems of critical infrastructure objects is developed. Using the proposed method, it is possible to solve the issue related to the possibility of calculating the amount of risks, which allows to assess the risk as a whole, taking into account the human factor in risk assessment, which is extremely important for critical infrastructure, especially in the energy sector. The proposed computing system can be used as part of a decision support system for assessing cybersecurity risks of information systems of critical infrastructure facilities. The results obtained can be used to assess the cybersecurity risk of information systems of critical infrastructure objects in the construction and implementation of information security management systems, integrated information protection systems in automated systems in the development of a threat model, security policy, and protection plan. Despite a significant number of approaches to solving this problem, it remains relevant for the entire world community.
Research of the impact on the ecology of the state of cybersecurity of the critical infrastructure objects Volodymyr Mokhor, Oleksandr Korchenko, Serhii Honchar, Maxsim Komarov, Alla Onyskova E3s Web of Conferences, 2021 The analysis of the impact on the ecology of the state of cybersecurity of critical infrastructure objects and the factors influencing the state of cybersecurity of the information system of the critical infrastructure object is performed. An explanation is given of why cybersecurity violations in automated process control systems can lead to consequences in the industrial sector and environmental impact. The need to develop effective and adequate proposals and measures for cybersecurity of information systems of the critical infrastructure objects is shown. The classification of assets that are the objects of cyberattacks by attackers and the categories of impact on the critical infrastructure objects are given. Approaches to determining the cyber threat risk factor of the critical infrastructure object and the relevance of threats are presented. The method of assessing the degree of possible damage from the implementation of information security threats is considered. The results of this analysis can be used to develop proposals and measures to avoid the effects of cyberattacks on the critical infrastructure objects. The prospect of further research is to develop a methodology for determining the relationship between specific cyberattacks and possible quantitative damage.
Guest editorial column: Special issue of journal of mobile multimedia “mobile communication and computing for internet of things and industrial automation” Journal of Mobile Multimedia, 2021
Analysis of cyber exercises approaches Ceur Workshop Proceedings, 2021
Critical IT Infrastructure Resource Distribution Algorithm Yaroslaw Dorogyy, Vasyl Tsurkan, Volodymyr Mokhor, Olena Doroha-Ivaniuk Proceedings of the 11th IEEE International Conference on Intelligent Data Acquisition and Advanced Computing Systems Technology and Applications Idaacs 2021, 2021
Conceptual approaches to the development and operation of the computer security system in the Ukraine Engineering Simulation, 1996
On specificity of application of various logical bases for constructing mathematical models of nonlinear objects using complex bitwise functions Engineering Simulation, 1995
Properties of systems of basis functions constructed using simple digit functions Izvestiya Vysshikh Uchebnykh Zavedenij Radioelektronika, 1995
RECENT SCHOLAR PUBLICATIONS
Adaptive security: strategic principles for complex socio-technical systems F Korobeynikov, V Mokhor Royal Society Open Science 13 (1) , 2026 2026 Citations: 3
Обґрунтування інвестицій в інформаційну безпеку: інтерпретація формули Блека–Шоулза V Mokhor, F Korobeynikov Ядерна та радіаційна безпека, 69-75 , 2025 2025
Transmorphance of socio-technical systems: A conceptual framework for adaptive security V Mokhor, F Korobeynikov International Science Journal of Management, Economics & Finance 4 (4), 71-77 , 2025 2025
Synergistic Foundations of a Resilient National Energy System: a Complex Systems Approach. V Mokhor, F Korobeynikov Èlektronnoe Modelirovanie 47 (3) , 2025 2025 Citations: 1
Гетерогенні безпілотні системи в небезпечних просторах: класифікація, сценарії використання та досягнення ситуаційної обізнаності. ВС Харченко, ГВ Фесенко, ІМ Клюшніков, ЄВ Брежнєв, СГ Стіренко, ... Èlektronnoe Modelirovanie 47 (3) , 2025 2025 Citations: 1
Justifying Investment in Information Security: An Interpretation of the Black–Scholes Formula V Mokhor, F Korobeynikov Ядерна та радіаційна безпека, 69-75 , 2025 2025
Next-Level Electric Power Intelligence: Ensuring Resilience at the Tactical Level V Mokhor, A Davydiuk 2024 14th International Conference on Dependable Systems, Services and … , 2024 2024
Парадигма нових ризиків кібербезпеки ВВ Мохор, ОО Бакалинський, ЯЮ Дорогий, ВВ Цуркан ІПМЕ ім. ГЄ Пухова НАН України , 2024 2024
Стійкість і резильєнтність у безпековому домені ВВ Мохор, ФО Коробейніков Реєстрація, зберігання і обробка даних 26 (1), 113-120 , 2024 2024 Citations: 2
Тенденція до змінювання парадигми забезпечування кібербезпеки ВВ Мохор, ОО Бакалинський, ЯЮ Дорогий, ВВ Цуркан ЛНУ ім. І. Франка , 2024 2024
Цифрова трансформація енергетики як запорука забезпечення її стійкості: Стенограма доповіді на засіданні Президії НАН України 4 жовтня 2023 року ВВ Мохор Visnik Nacional noi academii nauk Ukrai ni, 74-79 , 2023 2023 Citations: 1
Втілення парадигми резильєнтності в забезпечення функціонування критичної інфораструктури ЄС В Мохор, Ф Коробейніков, О Дибач, О Бакалинський Резильєнтність критичної інфраструктури – 2023 : збірник матеріалів науково … , 2023 2023
Симбіоз систем захисту інформації об’єктів критичної інфраструктури сфери енергетики ВВ Мохор, ОО Бакалинський, ЯЮ Дорогий, ВВ Цуркан ІПМЕ ім. ГЄ Пухова НАН України , 2023 2023
Model-based information security management systems architecture V Mokhor, O Bakalynskyi, Y Dorohyi, V Tsurkan ІНФОРМАЦІЙНІ ТЕХНОЛОГІЇ ТА БЕЗПЕКА, 139 , 2023 2023
Життєвий цикл систем управління інформаційною безпекою ВВ Мохор, ОО Бакалинський, ЯЮ Дорогий, ВВ Цуркан Національний технічний університет" Харківський політехнічний інститут" , 2023 2023
Функційна доцільність архітектури системи управління інформаційною безпекою ВВ Мохор, ОО Бакалинський, ЯЮ Дорогий, ВВ Цуркан НТУ" ХПІ" , 2022 2022
Характеристики функційної придатності архітектури систем управління інформаційною безпекою В Мохор, Я Дорогий, О Бакалинський, В Цуркан Київський національний університет імені Тараса Шевченка , 2022 2022
Документо-орієнтований підхід до побудови систем управління інформаційною безпекою В Мохор, О Бакалинський, Я Дорогий, В Цуркан ІНФОРМАЦІЙНІ ТЕХНОЛОГІЇ ТА БЕЗПЕКА, 20 , 2022 2022
Critical IT infrastructure resource distribution algorithm Y Dorogyy, V Tsurkan, V Mokhor, O Doroha-Ivaniuk 2021 11th IEEE International Conference on Intelligent Data Acquisition and … , 2021 2021 Citations: 10
Представлення системи глобальної маршрутизації мережі Інтернет як топологічного простору ВЮ Зубок, ВВ Мохор Реєстрація, зберігання і обробка даних 23 (1), 48-58 , 2021 2021
MOST CITED SCHOLAR PUBLICATIONS
Methods for the total risk assessment of cybersecurity of critical infrastructure facilities. Nucl. Rad. Saf. 2(82), 4–8 (2019) V Mokhor, S Gonchar, O Dybach Citations: 41
The Idea of the Construction of the Algebra of Risks on the Basis of the Theory of Complex Numbers V Mokhor, SF Honchar Electronic modeling 40 (4), 107-111 , 2018 2018.0 Citations: 25
Спроба локалізації ISO GUIDE 73: 2009 Risk management–Vocabulary В Мохор, О Богданов, О Крук, В Цуркан Безпека інформації, 12-22 , 2012 2012.0 Citations: 22
Verilog-HDL для моделирования и синтеза цифровых электронных схем ЮП Кондратенко, ВВ Мохор, СА Сидоренко Николаев: Изд-во НГГУ им. Петра Могилы , 2002 2002.0 Citations: 18
Cybersecurity risk assessment of information systems of critical infrastructure objects V Mokhor, S Honchar, A Onyskova 2020 IEEE International Conference on Problems of Infocommunications … , 2020 2020.0 Citations: 16
Analysis of information security risk assessment representation methods V Mokhor, O Bakalynskyi, V Tsurkan Information Technology and Technology 6 (1), 2411-1031.2018 , 2018 2018.0 Citations: 13
Information security assessment of computer systems by socio-engineering approach VV Mokhor, OV Tsurkan, RP Herasymov, VV Tsurkan CEUR Workshop Proceedings, 92-98 , 2017 2017.0 Citations: 13
Interpretation of the simple risk level dependence of its implementation in the terms of analytic geometry V Mokhor, O Bakalynskyi, O Bohdanov, V Tsurkan Information technology and security 5 (1), 71-82 , 2017 2017.0 Citations: 11
Наставления по кибербезопасности (ISO/IEC 27032: 2012) ВВ Мохор, АМ Богданов, АС Килевой К.:Три-К , 2013 2013.0 Citations: 11
Critical IT infrastructure resource distribution algorithm Y Dorogyy, V Tsurkan, V Mokhor, O Doroha-Ivaniuk 2021 11th IEEE International Conference on Intelligent Data Acquisition and … , 2021 2021.0 Citations: 10
Research of the impact on the ecology of the state of cybersecurity of the critical infrastructure objects V Mokhor, O Korchenko, S Honchar, M Komarov, A Onyskova E3S Web of Conferences 280, 09009 , 2021 2021.0 Citations: 9
Research of Validity of Presentation of Risks by Vectors in the Euclide Space V Mokhor, S Honchar Elektronne modelyuvannya 41 (4), 73-84 , 2019 2019.0 Citations: 9
Представлення оцінок ризиків інформаційної безпеки картою ризиків В Мохор, О Бакалинський, В Цуркан Information technology and security, 94-104 , 2018 2018.0 Citations: 9
Формування міжвузлових зв’язків в Інтернет з використанням методів теорії складних мереж В Мохор, В Зубок Київ:«Прометей , 2017 2017.0 Citations: 9
Использование RSA алгоритма для обеспечения задач криптографической защиты информации в современных информационно-телекоммуникационных системах АВ Жилин, АВ Корнейко, ВВ Мохор Захист інформації, 225-231 , 2013 2013.0 Citations: 9
Изложение стандарта «ISO 31000: 2009 RISK MANAGEMENT–PRINCIPLES AND GUIDELINES» на русском языке ВВ Мохор, АМ Богданов Das Management 3, 07-09 , 2011 2011.0 Citations: 9
About creating a multi-agent simulations model of processes pricing in the electricity market VV Mokhor, VA Evdokimov Electron. Model 42 (6), 3-17 , 2020 2020.0 Citations: 8
Построение оценок рисков безопасности информации на основе динамического множества актуальных угроз ВВ Мохор, А Богданов, О Крук, В Цуркан Збірник наукових праць Інституту проблем моделювання в енергетиці ім. ГЄ … , 2010 2010.0 Citations: 7
Estimation of cybersecurity risks of information systems of critical infrastructure objects V Mokhor, S Honchar Electronic Modeling 41 (6), 65-76 , 2019 2019.0 Citations: 6
