Tetiana A. Vakaliuk et al. CEUR Workshop Proceedings 1–3 Preface Tetiana A. Vakaliuk1,2,3,4 , Serhiy O. Semerikov3,2,1,5,4 1 Zhytomyr Polytechnic State University, 103 Chudnivsyka Str., Zhytomyr, 10005, Ukraine 2 Institute for Digitalisation of Education of the NAES of Ukraine, 9 M. Berlynskoho Str., Kyiv, 04060, Ukraine 3 Kryvyi Rih State Pedagogical University, 54 Universytetskyi Ave., Kryvyi Rih, 50086, Ukraine 4 Academy of Cognitive and Natural Sciences, 54 Gagarin Ave., Kryvyi Rih, 50086, Ukraine 5 Kryvyi Rih National University, 11 Vitalii Matusevych Str., Kryvyi Rih, 50027, Ukraine Abstract The 5th Edge Computing Workshop (doors 2025) is a peer-reviewed international edge computing event organized by Zhytomyr Polytechnic State University and the Academy of Cognitive and Natural Sciences. This workshop brings together researchers, academics, and industry practitioners to explore advancements in edge computing. In this distributed computing paradigm, computation and data storage are performed closer to the location where they are needed. The 2025 edition covers a diverse range of topics, including environmental monitoring systems, quality assurance for edge systems, integration of IoT with edge devices, advanced AI techniques, signal and image processing challenges, and messaging protocols for IoT systems. The workshop emphasizes theoretical research and practical implementations to identify emerging trends and innovative solutions in edge computing, which is increasingly vital due to the rise of the Internet of Things (IoT) and its demands for low latency, enhanced privacy, and real-time responsiveness. Keywords edge computing, Internet of Things (IoT), distributed computing, signal processing, MQTT messaging, Real-time applications 1. Introduction The 5th Edge Computing Workshop (doors 2025) is a peer-reviewed international event focused on the rapidly evolving field of edge computing, organized by Zhytomyr Polytechnic State University and the Academy of Cognitive and Natural Sciences. The Edge Computing Workshop (doors) is designed to bring together researchers, academics, and industry practitioners to explore advancements and applications in edge computing. Edge computing refers to a distributed computing paradigm where computation and data storage are performed closer to the location where they are needed—such as mobile devices, sensors, and end-users—rather than relying solely on centralized cloud systems. This approach is increasingly vital due to the rise of the Internet of Things (IoT), which demands low latency, enhanced privacy, and real-time responsiveness. The 2025 edition marks the fifth iteration of this workshop, building on previous years (e.g., doors 2024, 2023, etc.), and continues to foster discussions on the challenges and opportunities in this domain. It emphasizes theoretical research and practical implementations to identify emerging trends and innovative solutions. The workshop is particularly relevant in today’s digital landscape, where responsiveness, privacy, and situational awareness push computational capabilities to the "edge" of networks. It seeks to bridge the gap between central cloud systems and localized processing, encouraging innovative solutions to real-world problems. doors-2025: 5th Edge Computing Workshop, April 4, 2025, Zhytomyr, Ukraine " tetianavakaliuk@acnsci.org (T. A. Vakaliuk); semerikov@gmail.com (S. O. Semerikov) ~ http://acnsci.org/vakaliuk/ (T. A. Vakaliuk); https://acnsci.org/semerikov (S. O. Semerikov)  0000-0001-6825-4697 (T. A. Vakaliuk); 0000-0003-0789-0272 (S. O. Semerikov) © 2025 Copyright for this paper by its authors. Use permitted under Creative Commons License Attribution 4.0 International (CC BY 4.0). CEUR ceur-ws.org Workshop ISSN 1613-0073 Proceedings 1 Tetiana A. Vakaliuk et al. CEUR Workshop Proceedings 1–3 2. doors 2025 committees 2.1. Program committee co-chairs • Tetiana A. Vakaliuk, Zhytomyr State Polytechnic University, Ukraine • Serhiy O. Semerikov, Kryvyi Rih State Pedagogical University, Ukraine 2.2. Program committee • Ken Birman, Cornell University, USA • Aleksandr Cariow, West Pomeranian University of Technology, Poland • Nagender Kumar Suryadevara, University of Hyderabad, India • BongKyo Moon, Dongguk University, South Korea • Michael J. O’Grady, University College Dublin, Ireland • Xianzhi Wang, University of Technology Sydney, Australia • Alejandro Zunino, ISISTAN Research Institute, UNCPBA & CONICET, Argentina 2.3. Additional reviewers • Olexander Barmak, Khmelnytskyi National University, Ukraine • Balaji Shesharao Ingole, IEEE, USA • Valerii Kontsedailo, Inner Circle, Netherlands • Vyacheslav Kryzhanivskyy, R&D Seco Tools AB, Sweden • Nadiia Lobanchykova, Zhytomyr Polytechnic State University, Ukraine • Mykhailo Medvediev, ADA University, Azerbaijan • Franco Milano, University of Florence, Italy • Etibar Seyidzade, Baku Engineering University, Azerbaijan 2.4. Organizing committee • Tetiana Nikitchuk, Zhytomyr Polytechnic State University, Ukraine • Andrii Morozov, Zhytomyr Polytechnic State University, Ukraine • Serhiy Semerikov, Kryvyi Rih State Pedagogical University, Ukraine • Andrii Striuk, Kryvyi Rih National University, Ukraine • Tetiana Vakaliuk, Zhytomyr Polytechnic State University, Ukraine 3. Workshop overview Several presentations focused on systems for monitoring environmental conditions, particularly for climate and plant monitoring [1] and using regression analysis to identify patterns in atmospheric data [2]. These systems leverage IoT and edge computing to collect and analyze environmental data in real-time. Edge computing was a central focus, with presentations on quality assurance for edge systems [3], implementing knowledge distillation for medical imaging at the edge [4], and exploring the potential of Large Language Models on edge devices [5]. The integration of IoT with edge devices for various applications, including sports motion mechanization [6], was also discussed. Advanced AI techniques featured prominently, including: • Graph convolutional networks for traffic flow prediction [7]; • Multi-teacher knowledge distillation for cardiac MRI classification [4]; • Improved algorithms for UAV path planning [8]; 2 Tetiana A. Vakaliuk et al. CEUR Workshop Proceedings 1–3 • Feature fusion and attention enhancement for vehicle detection [9]; • Object detection models for remote sensing images [10]; • Speech enhancement using Bayesian estimators [11]. Several presentations addressed challenges in signal and image processing, including image denoising methods for dealing with shot noise and compound Poisson noise [12] and improved models for detecting randomly oriented objects in remote sensing images [10]. The workshop also covered messaging protocols for IoT systems, with an evaluation of TBMQ for peer-to-peer MQTT messaging [13], addressing the need for scalable and reliable communication in distributed IoT environments. The event encourages interdisciplinary dialogue, reflecting the multifaceted nature of edge computing, which intersects with computer science and engineering. 4. Conclusion This workshop appears to have brought together researchers and practitioners working at the intersec- tion of edge computing, IoT, environmental monitoring, and AI-powered analysis. Particular attention was paid to real-time applications and systems that can operate efficiently at the edge rather than requiring cloud infrastructure. Declaration on Generative AI: The authors have not employed any generative AI tools. References [1] N. S. Prasol, D. V. Furikhata, T. A. Vakaliuk, T. Y. Regenel, Integration of edge devices and IoT to create a climate monitoring system for plants, CEUR Workshop Proceedings (2025) 4–19. [2] D. V. Shevchenko, B. L. Holub, Regression analysis as a tool for identifying patterns in atmospheric air monitoring data, CEUR Workshop Proceedings (2025) 20–27. [3] V. O. Maliarskyi, V. P. Oleksiuk, Review of modern tools for edge computing systems quality assurance, CEUR Workshop Proceedings (2025) 67–80. [4] O. Chaban, E. Manziuk, O. Markevych, S. Petrovskyi, P. Radiuk, EMTKD at the edge: An adaptive multi-teacher knowledge distillation for robust cardiac MRI classification, CEUR Workshop Proceedings (2025) 42–57. [5] S. O. Semerikov, T. A. Vakaliuk, O. B. Kanevska, M. V. Moiseienko, I. I. Donchev, A. O. Kolhatin, LLM on the edge: the new frontier, CEUR Workshop Proceedings (2025) 137–161. [6] V. V. Romanuke, S. Y. Dementiev, S. A. Yaremko, An IoT-based system of mechanizing sport competition motion for perception improvement, CEUR Workshop Proceedings (2025) 81–96. [7] Y. Song, S. Wei, D. Liu, GADGN: A dual graph convolutional architecture for traffic flow prediction, CEUR Workshop Proceedings (2025) 28–41. [8] Z. Li, X. Zong, J. Hao, O. Kochan, Multi-UAV 3D path planning based on improved sparrow search algorithm, CEUR Workshop Proceedings (2025) 97–108. [9] M. Xue, Studying the efficiency and performance of the vehicle detection method based on feature fusion and attention enhancement, CEUR Workshop Proceedings (2025) 162–177. [10] I. A. Pilkevych, M. P. Romanchuk, O. M. Naumchak, D. L. Fedorchuk, L. M. Naumchak, Improved model for detecting randomly oriented objects on remote sensing images, CEUR Workshop Proceedings (2025) 118–126. [11] Q. T. The, Bayesian estimators-based microphone array speech enhancement in adverse environ- ment, CEUR Workshop Proceedings (2025) 127–136. [12] O. Kobylin, O. Putiatina, Some aspects of real-time image denoising influenced by shot noise and compound Poisson noise, CEUR Workshop Proceedings (2025) 109–117. [13] D. I. Shvaika, A. I. Shvaika, D. I. Landiak, V. O. Artemchuk, Scalable and reliable MQTT messaging: evaluating TBMQ for P2P scenarios, CEUR Workshop Proceedings (2025) 58–66. 3