Your search keyword '"Panagiotis K. Gkonis"' showing total 6 results

1. On the Performance Evaluation of a MIMO–WCDMA Transmission Architecture for Building Management Systems

Author

Eleftherios Tsampasis, Panagiotis K. Gkonis, Panagiotis Trakadas, and Theodοre Zahariadis

Subjects

building management systems, wideband code division multiple access (WCDMA), multiple input–multiple output (MIMO), Monte Carlo simulations, performance evaluation, Chemical technology, TP1-1185

Abstract

The goal of this study was to investigate the performance of a realistic wireless sensor nodes deployment in order to support modern building management systems (BMSs). A three-floor building orientation is taken into account, where each node is equipped with a multi-antenna system while a central base station (BS) collects and processes all received information. The BS is also equipped with multiple antennas; hence, a multiple input–multiple output (MIMO) system is formulated. Due to the multiple reflections during transmission in the inner of the building, a wideband code division multiple access (WCDMA) physical layer protocol has been considered, which has already been adopted for third-generation (3G) mobile networks. Results are presented for various MIMO orientations, where the mean transmission power per node is considered as an output metric for a specific signal-to-noise ratio (SNR) requirement and number of resolvable multipath components. In the first set of presented results, the effects of multiple access interference on overall transmission power are highlighted. As the number of mobile nodes per floor or the requested transmission rate increases, MIMO systems of a higher order should be deployed in order to maintain transmission power at adequate levels. In the second set of results, a comparison is performed among transmission in diversity combining and spatial multiplexing mode, which clearly indicate that the first case is the most appropriate solution for indoor communications.

Published

2018

2. A Cost-Efficient 5G Non-Public Network Architectural Approach: Key Concepts and Enablers, Building Blocks and Potential Use Cases.

Author

Panagiotis Trakadas, Lambros Sarakis, Anastasios E. Giannopoulos, Sotirios T. Spantideas, Nikolaos Capsalis, Panagiotis K. Gkonis, Panagiotis Karkazis, Giovanni Rigazzi, Angelos Antonopoulos 0001, Marta Amor Cambeiro, Sergio Gonzalez-Diaz, and Luís Conceição

Published

2021

3. An Artificial Intelligence-Based Collaboration Approach in Industrial IoT Manufacturing: Key Concepts, Architectural Extensions and Potential Applications.

Author

Panagiotis Trakadas, Pieter Simoens, Panagiotis K. Gkonis, Lambros Sarakis, Angelos Angelopoulos, Alfonso P. Ramallo-González, Antonio F. Skarmeta, Christos Trochoutsos, Daniel Calvomicron, Tomas Pariente, Keshav Chintamani, Izaskun Fernández, Aitor Arnaiz Irigaray, Josiane Xavier Parreira, Pierluigi Petrali, Nelly Leligou, and Panagiotis Karkazis

Published

2020

4. Hybrid Clouds for Data-Intensive, 5G-Enabled IoT Applications: An Overview, Key Issues and Relevant Architecture.

Author

Panagiotis Trakadas, Nikolaos Nomikos, Emmanouel T. Michailidis, Theodore B. Zahariadis, Federico M. Facca, David Breitgand, Stamatia Rizou, Xavi Masip, and Panagiotis K. Gkonis

Published

2019

5. A Cost-Efficient 5G Non-Public Network Architectural Approach: Key Concepts and Enablers, Building Blocks and Potential Use Cases

Author

Giovanni Rigazzi, Anastasios E. Giannopoulos, Lambros Sarakis, Panagiotis Karkazis, Luís Conceição, Sotirios T. Spantideas, Panagiotis Trakadas, Angelos Antonopoulos, Sergio Gonzalez-Diaz, Panagiotis K. Gkonis, Marta Amor Cambeiro, and Nikolaos Capsalis

Subjects

Technology, Dynamic network analysis, Computer science, Science, O-RAN, Distributed computing, Mission critical, TP1-1185, 02 engineering and technology, Network topology, Biochemistry, Article, Social Networking, Analytical Chemistry, AI/ML based network optimization, 0202 electrical engineering, electronic engineering, information engineering, Quality of experience, Electrical and Electronic Engineering, Instrumentation, Edge computing, network monitoring and telemetry, business.industry, Chemical technology, 020206 networking & telecommunications, Atomic and Molecular Physics, and Optics, private networks, time sensitive networking, Multimedia, Analytics, Θετικές Επιστήμες, Scalability, 020201 artificial intelligence & image processing, business, Wireless Technology, 5G, Private network

Abstract

The provision of high data rate services to mobile users combined with improved quality of experience (i.e., zero latency multimedia content) drives technological evolution towards the design and implementation of fifth generation (5G) broadband wireless networks. To this end, a dynamic network design approach is adopted whereby network topology is configured according to service demands. In parallel, many private companies are interested in developing their own 5G networks, also referred to as non-public networks (NPNs), since this deployment is expected to leverage holistic production monitoring and support critical applications. In this context, this paper introduces a 5G NPN architectural approach, supporting among others various key enabling technologies, such as cell densification, disaggregated RAN with open interfaces, edge computing, and AI/ML-based network optimization. In the same framework, potential applications of our proposed approach in real world scenarios (e.g., support of mission critical services and computer vision analytics for emergencies) are described. Finally, scalability issues are also highlighted since a deployment framework of our architectural design in an additional real-world scenario related to Industry 4.0 (smart manufacturing) is also analyzed.

Published

2021

6. An Artificial Intelligence-Based Collaboration Approach in Industrial IoT Manufacturing: Key Concepts, Architectural Extensions and Potential Applications

Author

Tomas Pariente, Aitor Arnaiz Irigaray, Izaskun Fernandez, Lambros Sarakis, Daniel Calvο, Pierluigi Petrali, Panagiotis K. Gkonis, Panagiotis Trakadas, Pieter Simoens, Keshav Chintamani, Antonio F. Skarmeta, Nelly Leligou, Josiane Xavier Parreira, Christos Trochoutsos, A. Angelopoulos, Alfonso P. Ramallo-González, and Panagiotis Karkazis

Subjects

Technology and Engineering, Industry 4.0, Computer science, Context (language use), 02 engineering and technology, lcsh:Chemical technology, Biochemistry, Article, Analytical Chemistry, sensing-based IIoT, smart, Manufacturing, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TP1-1185, industry 4.0, Electrical and Electronic Engineering, INTERNET, Instrumentation, Implementation, sensing, DEEP NEURAL-NETWORKS, smart sensing, business.industry, Information technology, 020206 networking & telecommunications, artificial intelligence, Atomic and Molecular Physics, and Optics, Analytics, Business intelligence, 020201 artificial intelligence & image processing, Artificial intelligence, business, industry 4, Architectural model, IoT manufacturing

Abstract

The digitization of manufacturing industry has led to leaner and more efficient production, under the Industry 4.0 concept. Nowadays, datasets collected from shop floor assets and information technology (IT) systems are used in data-driven analytics efforts to support more informed business intelligence decisions. However, these results are currently only used in isolated and dispersed parts of the production process. At the same time, full integration of artificial intelligence (AI) in all parts of manufacturing systems is currently lacking. In this context, the goal of this manuscript is to present a more holistic integration of AI by promoting collaboration. To this end, collaboration is understood as a multi-dimensional conceptual term that covers all important enablers for AI adoption in manufacturing contexts and is promoted in terms of business intelligence optimization, human-in-the-loop and secure federation across manufacturing sites. To address these challenges, the proposed architectural approach builds on three technical pillars: (1) components that extend the functionality of the existing layers in the Reference Architectural Model for Industry 4.0, (2) definition of new layers for collaboration by means of human-in-the-loop and federation, (3) security concerns with AI-powered mechanisms. In addition, system implementation aspects are discussed and potential applications in industrial environments, as well as business impacts, are presented.

Published

2020