Model of the dynamics of an open-loop automatic control system for military purposes

Source: Modern Information Technologies in the Sphere of Security and Defence; Vol. 53 No. 2 (2025); 35-42
Современные информационные технологии в сфере безопасности и обороны; Том 53 № 2 (2025); 35-42
Сучасні інформаційні технології у сфері безпеки та оборони; Том 53 № 2 (2025); 35-42

Subject Terms: automatic stabilisation system, вбудоване програмне забезпечення, математична модель, open-loop system, embedded software, hydraulic drive, гідропривід, mathematical model, розімкнена система

File Description: application/pdf

Access URL: https://sit.nuou.org.ua/article/view/332146

Analysis of the effectiveness of using specialized computing modules and libraries when implementing digital signal processing algorithms on the platform SoC

Source: Bulletin of the National Technical University "KhPI" A series of "Information and Modeling"; Vol. 1 No. 1 (13) (2025): Bulletin of the National Technical University "KhPI" A series of "Information and Modeling"; 112-128
Вестник Национального технического университета "ХПИ". Серия: Информатика и моделирование; Том 1 № 1 (13) (2025): Вісник Національного технічного університету "Харківський політехнічний інститут"; 112-128
Вісник Національного технічного університету "ХПІ". Серія: Iнформатика i моделювання; Том 1 № 1 (13) (2025): Вісник Національного технічного університету "Харківський політехнічний інститут"; 112-128

Subject Terms: вбудоване програмне забезпечення, пам'ять, швидке перетворення Фур'є, вбудовані системи, programmable logic, швидкодія, програмована логіка, embedded software, systems on a chip, мова програмування С, fast Fourier transform, memory, спеціалізовані бібліотеки, оптимізація, embedded systems, IP-core, specialized libraries, системи на кристалі, optimization, performance, C programming language

File Description: application/pdf

Access URL: http://pim.khpi.edu.ua/article/view/332908

Модель динаміки розімкненої системи автоматичного керування військового призначення

Authors: Vasyl Kuzavkov, Andrii Matsayenko, Viacheslav Solodovnyk

Source: Sučasnì Informacìjnì Tehnologìï u Sferì Bezpeki ta Oboroni, Vol 53, Iss 2 (2025)

Subject Terms: вбудоване програмне забезпечення, розімкнена система, гідропривід, математична модель, Industrial safety. Industrial accident prevention, T55-55.3

File Description: electronic resource

Relation: https://sit.nuou.org.ua/article/view/332146; https://doaj.org/toc/2311-7249; https://doaj.org/toc/2410-7336

Access URL: https://doaj.org/article/7bf97ed2cfec4e0c90f7c47da0e1a882

CONSTRUCTION OF A VERIFIABLE TEST SEQUENCE FOR ASSESSING THE TECHNICAL CONDITION OF OBJECTS WITH EMBEDDED SOFTWARE

Source: Ukrainian Scientific Journal of Information Security; Vol. 30 No. 1 (2024): Ukrainian Scientific Journal of Information Security ; 29-36
Безопасность информации; Том 30 № 1 (2024): Безпека інформації; 29-36
Безпека інформації; Том 30 № 1 (2024): Безпека інформації; 29-36

Subject Terms: вбудоване програмне забезпечення, модель, model, технічний стан, physical integrity, communication equipment, mathematical modeling, фізична цілісність, embedded software, математичне моделювання, technical condition, комунікаційне обладнання, діагностична інформація, diagnostic information

File Description: application/pdf

Access URL: https://jrnl.nau.edu.ua/index.php/Infosecurity/article/view/18578

Use of models for assessment of change parameters of the physical environment of data transmission for technical diagnostic of radio-electronic equipment

Source: Modern Information Technologies in the Sphere of Security and Defence; Vol. 48 No. 3 (2023); 75-82
Современные информационные технологии в сфере безопасности и обороны; Том 48 № 3 (2023); 75-82
Сучасні інформаційні технології у сфері безпеки та оборони; Том 48 № 3 (2023); 75-82

Subject Terms: проводова лінія, вбудоване програмне забезпечення, технічна діагностика, волоконно-оптична лінія, енерго-часовий параметр, канал передачі, technical diagnostics, wire line, transmission channel, embedded software, energy-time parameter, fiber optical line

File Description: application/pdf

Access URL: http://sit.nuou.org.ua/article/view/290126

Використання моделей оцінювання зміни параметрів фізичного середовища передачі даних для технічного діагностування радіо-електронного обладнання

Authors: Anatolii Minochkin, Vasyl Kuzavkov, Yuliia Bolotiuk

Source: Sučasnì Informacìjnì Tehnologìï u Sferì Bezpeki ta Oboroni, Vol 48, Iss 3 (2024)

Subject Terms: технічна діагностика, канал передачі, волоконно-оптична лінія, проводова лінія, вбудоване програмне забезпечення, енерго-часовий параметр, Industrial safety. Industrial accident prevention, T55-55.3

File Description: electronic resource

Relation: https://sit.nuou.org.ua/article/view/290126; https://doaj.org/toc/2311-7249; https://doaj.org/toc/2410-7336

Access URL: https://doaj.org/article/b769901323c44f109b6b40e5250eaa82

PRACTICAL USE OF THE MODEL FOR EVALUATING CHANGES IN THE PARAMETERS OF THE OPTICAL FIBER DATA TRANSMISSION MEDIUM

Source: Ukrainian Information Security Research Journal; Vol. 25 No. 3 (2023): Ukrainian Scientific Journal of Information Security; 101-107
Защита информации; Том 25 № 3 (2023): Захист інформації; 101-107
Захист інформації; Том 25 № 3 (2023): Захист інформації; 101-107

Subject Terms: вбудоване програмне забезпечення, технічна діагностика, енерго-часовий параметр, канал передачі, technical diagnostics, transmission channel, optical fiber line, оптоволоконна лінія, embedded software, energy-time parameter

File Description: application/pdf

Access URL: https://jrnl.nau.edu.ua/index.php/ZI/article/view/17934

Development of Digital Compass Based on AVR Microcontroller and MEMS Accelerometer- Magnetometer Module LSM303DLHC

Authors: Holovatyy, A., Teslyuk, V., Kolesnyk, K., Tabala, V.

Contributors: Національний університет 'Львівська політехніка', Lviv Polytechnic National University

Source: Computer Design Systems. Theory and Practice. :12-26

Subject Terms: апаратно-програмна платформа Arduino Uno R3, вбудоване програмне забезпечення, Proteus Design Suite, 4. Education, МК ATmega328P-PU, акселерометр, магнітометр, embedded software, цифровий компас, 519.2.4, 681.5, Arduino Uno R3, accelerometer, мова програмування C, САПР Proteus Design Suite, digital compass, МЕМС модуль LSM303DLHC, 621.382, magnetometer, MEMS module LSM303DLHC, Arduino IDE, AVR microcontroller ATmega328P-PU, середовище програмування Arduino IDE для МК платформи Arduino, C programming language

File Description: application/pdf; image/png

Access URL: http://science.lpnu.ua/sites/default/files/journal-paper/2020/apr/21320/2.pdf
https://ena.lpnu.ua/handle/ntb/55843

Development of digital compass based on AVR microcontroller and MEMS ACCELEROMETER-magnetometer module LSM303DLHC ; Розробка цифрового компасу на AVR мікроконтролері та MEMS – модулі АКСЕЛЕРОМЕТРА – магнітометра LSM303DLHC

Authors: Головатий, А., Теслюк, В., Колесник, К. К., Табала, В. В., Holovatyy, A., Teslyuk, V., Kolesnyk, K., Tabala, V.

Contributors: Національний університет “Львівська політехніка”, Lviv Polytechnic National University

Subject Terms: цифровий компас, апаратно-програмна платформа Arduino Uno R3, МК ATmega328P-PU, акселерометр, магнітометр, МЕМС модуль LSM303DLHC, САПР Proteus Design Suite, мова програмування C, середовище програмування Arduino IDE для МК платформи Arduino, вбудоване програмне забезпечення, digital compass, Arduino Uno R3, AVR microcontroller ATmega328P-PU, accelerometer, magnetometer, MEMS module LSM303DLHC, Proteus Design Suite, C programming language, Arduino IDE, embedded software, 519.2.4, 681.5, 621.382

Subject Geographic: Львів, Lviv

File Description: 12-26; application/pdf; image/png

Relation: Computer Design Systems. Theory and Practice, 1 (1), 2019; https://www.st.com/content/st_com/en/products/mems-and-sensors/ecompasses.html; https://www.memsic.com/magnetic-sensors/; http://en.wikipedia.org/wiki/Compass; http://en.wikipedia.org/wiki/Lodestone; https://en.wikipedia.org/wiki/Earth%27s_magnetic_field; https://www.livescience.com/32732-how-does-a-compass-work.html; http://www.cypress.com/?docID=221; http://cache.freescale.com/files/sensors/doc/app_note/AN4248.pdf; https://www.pololu.com/file/0J434/LSM303DLH-compass-app-note.pdf; https://www.st.com/en/mems-and-sensors/lsm303dlhc.html; https://www.st.com/resource/en/datasheet/DM00027543.pdf; 1. Electronic resource: https://www.st.com/content/st_com/en/products/mems-and-sensors/ecompasses.html; 2. Electronic resource: https://www.memsic.com/magnetic-sensors/; 3. Compass.” [Online]. Available: http://en.wikipedia.org/wiki/Compass[2] “Lodestone”. [Online] .Available: http://en.wikipedia.org/wiki/Lodestone; 4. Electronic resource: https://en.wikipedia.org/wiki/Earth%27s_magnetic_field; 5. Electronic resource: https://www.livescience.com/32732-how-does-a-compass-work.html; 6. Grygorenko V., “Cypress application note – magnetic compass with tilt compensation-an2272”. [Online].Available: http://www.cypress.com/?docID=221.; 7. Application note AN4248: “Implementing a Tilt-Compensated eCompass using Accelerometer and Mag-netometer Sensors”, 2012, http://cache.freescale.com/files/sensors/doc/app_note/AN4248.pdf.; 8. Application note AN3192: “Using LSM303DLH for a tilt compensated electronic compass” https://www.pololu.com/file/0J434/LSM303DLH-compass-app-note.pdf.; 9. Electronic resource: https://www.st.com/en/mems-and-sensors/lsm303dlhc.html; 3. Compass." [Online]. Available: http://en.wikipedia.org/wiki/Compass[2] "Lodestone". [Online] .Available: http://en.wikipedia.org/wiki/Lodestone; 6. Grygorenko V., "Cypress application note – magnetic compass with tilt compensation-an2272". [Online].Available: http://www.cypress.com/?docID=221.; 7. Application note AN4248: "Implementing a Tilt-Compensated eCompass using Accelerometer and Mag-netometer Sensors", 2012, http://cache.freescale.com/files/sensors/doc/app_note/AN4248.pdf.; 8. Application note AN3192: "Using LSM303DLH for a tilt compensated electronic compass" https://www.pololu.com/file/0J434/LSM303DLH-compass-app-note.pdf.; Development of digital compass based on AVR microcontroller and MEMS ACCELEROMETER-magnetometer module LSM303DLHC / A. Holovatyy, V. Teslyuk, K. Kolesnyk, V. Tabala // Computer Design Systems. Theory and Practice. — Lviv : Lviv Politechnic Publishing House, 2019. — Vol 1. — No 1. — P. 12–26.; https://ena.lpnu.ua/handle/ntb/55843

Availability: https://ena.lpnu.ua/handle/ntb/55843

Моделювання динамічних мереж міської інфраструктури з використанням кіберфізичних систем ; Modeling of the city infrastructure dynamic networks using cyber-physical systems

Authors: Коваль, Андрій Андрійович, Koval, Andrii Andriiovych

Contributors: Гром'як, Роман Сильвестрович, Тиш, Євгенія Володимирівна, ТНТУ ім. І. Пулюя, Факультет комп’ютерно-інформаційних систем і програмної інженерії, Кафедра комп’ютерних наук, м. Тернопіль, Україна

Subject Terms: моделювання, modelling, мережа, network, кіберфізичні системи, cyber physical systems, архітектура програмного забезпечення, software architect, класифікація систем, system classification, вбудоване програмне забезпечення, embedded software, обчислення, computing, мікроконтролер, microcontroller, 517.5

Subject Geographic: ТНТУ ім. І.Пулюя, ФІС, м. Тернопіль, Україна, UA

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