Chrysostomos-Athanasios Katsigiannis
Short CV: Chrysostomos-Athanasios Katsigiannis was born in 2001 in Athens, Greece. In 2016 he received the Michigan Certificate of Proficiency in English and in 2018 he received the Goethe Zertifikat B2 (B2 Certificate for the German Language). Later, in 2019 he graduated high school from Elliniki Paideia and began studying as an undergraduate student in the Department of Computer Engineering and Informatics at the University of Patras in September 2019. He has been a member of the Distributed System and Telematics Lab since 2022 and his fields of interest are 5th generation mobile telecommunication networks and artificial intelligence.
Conferences
Tsachrelias, Konstantinos; Katsigiannis, Chrysostomos-Athanasios; Kokkinos, Vasileios; Gkamas, Apostolos; Bouras, Christos; Pouyioutas, Philippos
Efficient User Equipment Distribution in DUDe 5G Network using Linear Assignment Algorithms Conference
16th Internaional Congress on Ultra Modern Telecommunications and Control Systems and Workshops (ICUMT 2024), November 26 – 28, 2024, Grand Canaria Spain, pp. 1-6 (to appear), 2024.
Abstract | Links | BibTeX | Tags:
@conference{nokey,
title = {Efficient User Equipment Distribution in DUDe 5G Network using Linear Assignment Algorithms},
author = {Konstantinos Tsachrelias and Chrysostomos-Athanasios Katsigiannis and Vasileios Kokkinos and Apostolos Gkamas and Christos Bouras and Philippos Pouyioutas},
url = {https://telematics.upatras.gr/icumt2024_bouras/},
year = {2024},
date = {2024-11-26},
urldate = {2024-11-26},
booktitle = {16th Internaional Congress on Ultra Modern Telecommunications and Control Systems and Workshops (ICUMT 2024), November 26 – 28, 2024, Grand Canaria Spain, pp. 1-6 (to appear)},
pages = {1 - 6 },
abstract = {In the context of 5G networks, efficient resource allocation plays a crucial role in meeting the diverse and demanding requirements of modern applications. This paper presents a novel approach for optimizing User Equipment (UE) distribution in Downlink/Uplink Decoupling (DUDe) 5G networks through the application of Linear Assignment Algorithms (LAAs). The proposed multi-objective framework intelligently allocates UEs to DUDe Base Stations, aiming to maximize network performance, achieve load balancing, enhance Signal-to-Noise Ratio (SNR), and optimize energy efficiency. The findings hold significant implications for network operators, facilitating the advancement of 5G infrastructures to meet the ever-increasing demand for seamless and high-quality connectivity.},
keywords = {},
pubstate = {published},
tppubtype = {conference}
}
In the context of 5G networks, efficient resource allocation plays a crucial role in meeting the diverse and demanding requirements of modern applications. This paper presents a novel approach for optimizing User Equipment (UE) distribution in Downlink/Uplink Decoupling (DUDe) 5G networks through the application of Linear Assignment Algorithms (LAAs). The proposed multi-objective framework intelligently allocates UEs to DUDe Base Stations, aiming to maximize network performance, achieve load balancing, enhance Signal-to-Noise Ratio (SNR), and optimize energy efficiency. The findings hold significant implications for network operators, facilitating the advancement of 5G infrastructures to meet the ever-increasing demand for seamless and high-quality connectivity.
Katsigiannis, Chrysostomos-Athanasios; Tsachrelias, Konstantinos; Kokkinos, Vasileios; Gkamas, Apostolos; Bouras, Christos; Pouyioutas, Philippos
Enhancing Real – Time IoT Applications: Latency Reduction Techniques in 5G MIMO Networks (to appear) Conference
The 19th International Conference on Broadband and Wireless Computing, Communication and Applications Communication and Applications (BWCCA 2024), November 13 – 15, 2024, San Benedetto del Tronto, Italy, pp.1-6 , vol. -, 2024.
Abstract | Links | BibTeX | Tags:
@conference{nokey,
title = {Enhancing Real – Time IoT Applications: Latency Reduction Techniques in 5G MIMO Networks (to appear)},
author = {Chrysostomos-Athanasios Katsigiannis and Konstantinos Tsachrelias and Vasileios Kokkinos and Apostolos Gkamas and Christos Bouras and Philippos Pouyioutas},
url = {https://telematics.upatras.gr/iot_bwcca_2024_submitted_lncs-final-2/},
year = {2024},
date = {2024-11-03},
urldate = {2024-11-03},
booktitle = {The 19th International Conference on Broadband and Wireless Computing, Communication and Applications Communication and Applications (BWCCA 2024), November 13 – 15, 2024, San Benedetto del Tronto, Italy, pp.1-6 },
volume = {-},
pages = {1 - 6 },
abstract = {In the ever-growing field of 5G technology, Massive Multiple Input Multiple Output (MIMO) systems hold the promise of substantial improvements in net-work capacity and efficiency. However, the demand for low latency, imposed by real-time Internet of Things (IoT) applications presents some significant obsta-cles. This study delves into novel approaches to reducing latency within 5G MIMO setups, focusing particularly on the integration of shortened Transmission Time Intervals (TTIs) and preemptive scheduling tactics. Through simulations in-volving a small-scale MIMO configuration servicing multiple IoT devices, this study thoroughly evaluates the effects of these methods on transmission latency. The desired result is to demonstrate that the adoption of reduced TTIs notably mitigates overall latency, thereby augmenting the efficacy of time-sensitive IoT tasks such as industrial automation and healthcare monitoring systems. This re-search not only contributes to the theoretical progression of 5G communications but also furnishes practical insights for network operators and system designers trying to fine-tune 5G networks for evolving IoT environments. The simulation results indicate that the proposed techniques significantly reduce latency by ap-proximately 30% compared to standard configurations, particularly benefiting high-priority IoT applications. These findings highlight the effectiveness of shortened TTIs and preemptive scheduling in enhancing the performance of real-time IoT tasks within 5G MIMO networks.},
keywords = {},
pubstate = {published},
tppubtype = {conference}
}
In the ever-growing field of 5G technology, Massive Multiple Input Multiple Output (MIMO) systems hold the promise of substantial improvements in net-work capacity and efficiency. However, the demand for low latency, imposed by real-time Internet of Things (IoT) applications presents some significant obsta-cles. This study delves into novel approaches to reducing latency within 5G MIMO setups, focusing particularly on the integration of shortened Transmission Time Intervals (TTIs) and preemptive scheduling tactics. Through simulations in-volving a small-scale MIMO configuration servicing multiple IoT devices, this study thoroughly evaluates the effects of these methods on transmission latency. The desired result is to demonstrate that the adoption of reduced TTIs notably mitigates overall latency, thereby augmenting the efficacy of time-sensitive IoT tasks such as industrial automation and healthcare monitoring systems. This re-search not only contributes to the theoretical progression of 5G communications but also furnishes practical insights for network operators and system designers trying to fine-tune 5G networks for evolving IoT environments. The simulation results indicate that the proposed techniques significantly reduce latency by ap-proximately 30% compared to standard configurations, particularly benefiting high-priority IoT applications. These findings highlight the effectiveness of shortened TTIs and preemptive scheduling in enhancing the performance of real-time IoT tasks within 5G MIMO networks.
Katsigiannis, Chrysostomos-Athanasios; Tsachrelias, Konstantinos; Kokkinos, Vasileios; Bouras, Christos; Gkamas, Apostolos; Pouyioutas, Philippos
Energy Efficiency Analysis of DUDe 5G Networks Conference
The 15th International Conference on Ubiquitous and Future Networks (ICUFN 2024), Jyly 2 – 5, 2024, Budapest, Hungary, 2024.
Abstract | Links | BibTeX | Tags:
@conference{4664,
title = {Energy Efficiency Analysis of DUDe 5G Networks},
author = {Chrysostomos-Athanasios Katsigiannis and Konstantinos Tsachrelias and Vasileios Kokkinos and Christos Bouras and Apostolos Gkamas and Philippos Pouyioutas},
url = {https://telematics.upatras.gr/wp-content/uploads/2024/06/icufn2024_submitted.pdf},
year = {2024},
date = {2024-01-01},
urldate = {2024-01-01},
booktitle = {The 15th International Conference on Ubiquitous and Future Networks (ICUFN 2024), Jyly 2 – 5, 2024, Budapest, Hungary},
abstract = {In this paper we evaluate the energy efficiency of Downlink/Uplink Decoupling (DUDe) systems by considering the energy consumption of each Base Station (BS) and the communication overhead between the BSs and User Equipment (UE). Through extensive simulations, the energy efficiency of DUDe systems is evaluated under various scenarios, such as different UE densities, Base Stations (BSs) configurations, and traffic patterns. The simulation results indicate that the proposed DUDe system can achieve significant energy savings compared to traditional centralized 5G systems. The impact of various parameters on energy efficiency is also analyzed, providing guidelines for designing energy-efficient DUDe systems. The paper emphasizes the significance of energy-efficient design in 5G networks, as it can significantly reduce the operational costs and carbon footprint of the network.},
keywords = {},
pubstate = {published},
tppubtype = {conference}
}
In this paper we evaluate the energy efficiency of Downlink/Uplink Decoupling (DUDe) systems by considering the energy consumption of each Base Station (BS) and the communication overhead between the BSs and User Equipment (UE). Through extensive simulations, the energy efficiency of DUDe systems is evaluated under various scenarios, such as different UE densities, Base Stations (BSs) configurations, and traffic patterns. The simulation results indicate that the proposed DUDe system can achieve significant energy savings compared to traditional centralized 5G systems. The impact of various parameters on energy efficiency is also analyzed, providing guidelines for designing energy-efficient DUDe systems. The paper emphasizes the significance of energy-efficient design in 5G networks, as it can significantly reduce the operational costs and carbon footprint of the network.
Tsachrelias, Konstantinos; Katsigiannis, Chrysostomos-Athanasios; Kokkinos, Vasileios; Gkamas, Apostolos; Bouras, Christos; Pouyioutas, Philippos
Optimizing Resource Allocation in 5G MIMO Networks Using DUDe Techniques Conference
14th IEEE/IET International Symposium on Communication Systems, Networks and Digital Signal Processing (CNDSP 2024), July 17 – 19, 2024, Rome Italy, 2024.
Abstract | Links | BibTeX | Tags:
@conference{4663b,
title = {Optimizing Resource Allocation in 5G MIMO Networks Using DUDe Techniques},
author = {Konstantinos Tsachrelias and Chrysostomos-Athanasios Katsigiannis and Vasileios Kokkinos and Apostolos Gkamas and Christos Bouras and Philippos Pouyioutas},
url = {https://telematics.upatras.gr/csndsp-2024/},
year = {2024},
date = {2024-01-01},
urldate = {2024-01-01},
booktitle = {14th IEEE/IET International Symposium on Communication Systems, Networks and Digital Signal Processing (CNDSP 2024), July 17 – 19, 2024, Rome Italy},
pages = {454 - 459},
abstract = {In the landscape of 5G networks, efficient resource allocation stands as a critical factor in meeting the diverse demands of applications and users. This paper delves into optimizing resource allocation within 5G Multiple Input Multiple Output (MIMO) networks by leveraging Downlink/Uplink Decoupling (DUDe) techniques. MIMO technology, enabling the simultaneous transmission of multiple data streams, holds promise for boosting spectral efficiency. However, accommodating the dynamic and diverse user requirements poses a significant challenge in resource allocation. By employing advanced DUDe techniques, this research aims to dynamically allocate resources in 5G MIMO networks, seeking to enhance throughput, minimize latency, and optimize user satisfaction. Through simulation-based analysis, this paper highlights the efficacy of the proposed approach in significantly improving network performance and resource utilization.},
keywords = {},
pubstate = {published},
tppubtype = {conference}
}
In the landscape of 5G networks, efficient resource allocation stands as a critical factor in meeting the diverse demands of applications and users. This paper delves into optimizing resource allocation within 5G Multiple Input Multiple Output (MIMO) networks by leveraging Downlink/Uplink Decoupling (DUDe) techniques. MIMO technology, enabling the simultaneous transmission of multiple data streams, holds promise for boosting spectral efficiency. However, accommodating the dynamic and diverse user requirements poses a significant challenge in resource allocation. By employing advanced DUDe techniques, this research aims to dynamically allocate resources in 5G MIMO networks, seeking to enhance throughput, minimize latency, and optimize user satisfaction. Through simulation-based analysis, this paper highlights the efficacy of the proposed approach in significantly improving network performance and resource utilization.
Katsigiannis, Chrysostomos-Athanasios; Gkamas, Apostolos; Tsachrelias, Konstantinos; Bouras, Christos; Kokkinos, Vasileios; Pouyioutas, Philippos
Simulation Based Energy Efficiency Analysis of DUDe 5G Networks Conference
The Twentieth Advanced International Conference on Telecommunications (AICT 2024), April 14 – 18, 2024, Venice, Italy, 2024.
Abstract | Links | BibTeX | Tags:
@conference{4661,
title = {Simulation Based Energy Efficiency Analysis of DUDe 5G Networks},
author = {Chrysostomos-Athanasios Katsigiannis and Apostolos Gkamas and Konstantinos Tsachrelias and Christos Bouras and Vasileios Kokkinos and Philippos Pouyioutas},
url = {https://telematics.upatras.gr/wp-content/uploads/2024/06/AICT2024_Camera_Ready-00000002.pdf},
year = {2024},
date = {2024-01-01},
urldate = {2024-01-01},
booktitle = {The Twentieth Advanced International Conference on Telecommunications (AICT 2024), April 14 – 18, 2024, Venice, Italy},
pages = {1 - 6},
abstract = {To be able to respond to the explosively increased data traffic demand of 5G and beyond networks (Internet of Things (IoT) , Voice/Video calls, Peer2Peer (P2P) software, etc.), one of the most promising technologies are densified Heterogeneous Networks (HetNets). In HetNets, base stations are brought closer to users with the placement of small base stations, which results in better spectral and energy efficiency for cellular systems. However, the HetNet topology challenges traditional cellular systems. One of the most important challenges is user association. Aiming to avoid the drawback caused by Downlink/Uplink Coupling (DUCo) access in HetNets user association, a Downlink/Uplink Decoupling DUDe Access approach has emerged. By allowing access points in the uplink and downlink association to be different, DUDe greatly improves the uplink performance of HetNets. In this paper, we evaluate energy efficiency and resource allocation of DUDe approach.},
keywords = {},
pubstate = {published},
tppubtype = {conference}
}
To be able to respond to the explosively increased data traffic demand of 5G and beyond networks (Internet of Things (IoT) , Voice/Video calls, Peer2Peer (P2P) software, etc.), one of the most promising technologies are densified Heterogeneous Networks (HetNets). In HetNets, base stations are brought closer to users with the placement of small base stations, which results in better spectral and energy efficiency for cellular systems. However, the HetNet topology challenges traditional cellular systems. One of the most important challenges is user association. Aiming to avoid the drawback caused by Downlink/Uplink Coupling (DUCo) access in HetNets user association, a Downlink/Uplink Decoupling DUDe Access approach has emerged. By allowing access points in the uplink and downlink association to be different, DUDe greatly improves the uplink performance of HetNets. In this paper, we evaluate energy efficiency and resource allocation of DUDe approach.
Katsigiannis, Chrysostomos-Athanasios; Gkamas, Apostolos; Tsachrelias, Konstantinos; Bouras, Christos; Kokkinos, Vasileios; Pouyioutas, Philippos
Power Consumption Analysis in DUDe 5G MIMO Networks Conference
15th International Conference on Network of the Future (NoF 2024), October 2 – 4, 2024, Barcelona, Spain, 2024.
Abstract | Links | BibTeX | Tags:
@conference{4674,
title = {Power Consumption Analysis in DUDe 5G MIMO Networks},
author = {Chrysostomos-Athanasios Katsigiannis and Apostolos Gkamas and Konstantinos Tsachrelias and Christos Bouras and Vasileios Kokkinos and Philippos Pouyioutas},
url = {https://telematics.upatras.gr/1571017724nof2024-2/},
year = {2024},
date = {2024-01-01},
urldate = {2024-01-01},
booktitle = {15th International Conference on Network of the Future (NoF 2024), October 2 – 4, 2024, Barcelona, Spain},
abstract = {The advent of 5G technology has brought unprecedented advancements in wireless communication, promising higher data rates and improved user experiences. However, the implementation of Multiple-Input Multiple- Output (MIMO) techniques in 5G networks has significantly increased power consumption, posing a challenge to sustainability and operational costs. This study conducts a comparative analysis of energy efficiency in 5G MIMO networks, specifically between Downlink Uplink Coupling (DUCo) and Downlink Uplink Decoupling (DUDe) techniques. By examining the remaining power in the Base Stations (BSs) of the implemented Heterogeneous Network (HetNet), this analysis evaluates the potential of DUDe over DUCo in managing power consumption. The findings of this study aim to assist network operators, researchers, and policymakers in developing greener and more sustainable 5G infrastructures for a cleaner, energyefficient future.},
keywords = {},
pubstate = {published},
tppubtype = {conference}
}
The advent of 5G technology has brought unprecedented advancements in wireless communication, promising higher data rates and improved user experiences. However, the implementation of Multiple-Input Multiple- Output (MIMO) techniques in 5G networks has significantly increased power consumption, posing a challenge to sustainability and operational costs. This study conducts a comparative analysis of energy efficiency in 5G MIMO networks, specifically between Downlink Uplink Coupling (DUCo) and Downlink Uplink Decoupling (DUDe) techniques. By examining the remaining power in the Base Stations (BSs) of the implemented Heterogeneous Network (HetNet), this analysis evaluates the potential of DUDe over DUCo in managing power consumption. The findings of this study aim to assist network operators, researchers, and policymakers in developing greener and more sustainable 5G infrastructures for a cleaner, energyefficient future.
Tsachrelias, Konstantinos; Gkamas, Apostolos; Katsigiannis, Chrysostomos-Athanasios; Bouras, Christos; Kokkinos, Vasileios; Pouyioutas, Philippos
On the Optimization of User Allocation in Heterogeneous 5G Networks Using DUDe Techniques Conference
The 14th International Conference on Ubiquitous and Future Networks (ICUFN 2023), July 4 – 7, 2023, Paris France, pp. 521-526, 2023.
Abstract | Links | BibTeX | Tags:
@conference{4652,
title = {On the Optimization of User Allocation in Heterogeneous 5G Networks Using DUDe Techniques},
author = {Konstantinos Tsachrelias and Apostolos Gkamas and Chrysostomos-Athanasios Katsigiannis and Christos Bouras and Vasileios Kokkinos and Philippos Pouyioutas},
url = {https://telematics.upatras.gr/wp-content/uploads/2024/06/ICUFN2023_Bouras.pdf},
year = {2023},
date = {2023-01-01},
urldate = {2023-01-01},
booktitle = {The 14th International Conference on Ubiquitous and Future Networks (ICUFN 2023), July 4 – 7, 2023, Paris France, pp. 521-526},
pages = {521 – 526},
abstract = {In previous years, 3G and 4G cellular homogeneous networks configured with macro Base Stations (BSs) relied only on the downlink signal, even though transmission power and interference levels differ significantly between uplink and downlink. In 5G Heterogeneous Networks (HetNet), a new generation which have multiple BSs of different types such as Femto BS and Macro BS, there is the possibility of choosing to receive the data from one BS and transmit them to a different BS, and therefore decoupling the uplink and downlink. Especially, the increasing demand for faster, more reliable, and efficient connectivity has made the optimization of User Equipment (UE) allocation in 5G networks a crucial task. To tackle the challenges posed by heterogeneous 5G networks, this study compares and evaluates the performance of Downlink/Uplink Decoupling (DUDe) and traditional Downlink/Uplink Coupled (DUCo) user allocation approaches. Simulation results show that DUDe UE allocation outperforms DUCo by providing improved network performance and more efficient utilization of network resources in diverse network conditions. These findings have important implications for the design and optimization of 5G networks and provide valuable insights for researchers and practitioners in the field.},
keywords = {},
pubstate = {published},
tppubtype = {conference}
}
In previous years, 3G and 4G cellular homogeneous networks configured with macro Base Stations (BSs) relied only on the downlink signal, even though transmission power and interference levels differ significantly between uplink and downlink. In 5G Heterogeneous Networks (HetNet), a new generation which have multiple BSs of different types such as Femto BS and Macro BS, there is the possibility of choosing to receive the data from one BS and transmit them to a different BS, and therefore decoupling the uplink and downlink. Especially, the increasing demand for faster, more reliable, and efficient connectivity has made the optimization of User Equipment (UE) allocation in 5G networks a crucial task. To tackle the challenges posed by heterogeneous 5G networks, this study compares and evaluates the performance of Downlink/Uplink Decoupling (DUDe) and traditional Downlink/Uplink Coupled (DUCo) user allocation approaches. Simulation results show that DUDe UE allocation outperforms DUCo by providing improved network performance and more efficient utilization of network resources in diverse network conditions. These findings have important implications for the design and optimization of 5G networks and provide valuable insights for researchers and practitioners in the field.