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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Implementace mechanismů zajišťujících “RAN Slicing” v simulačním nástroji Network Simulator 3 / Implementation of mechanisms ensuring “RAN Slicing” in the simulation tool Network Simulator 3

Motyčka, Jan January 2021 (has links)
This thesis deals with the topic of network slicing technology in 5G networks, mainly on the RAN part. In the theoretical part, basic principles of 5G network slicing in core network part and RAN part are presented. Practical part contains a simulation scenario created in NS3 simulator with LENA 5G module. Results of this simulation are presented and discussed with the emphasis on RAN slicing.
2

Reinforcement Learning Based Resource Allocation for Network Slicing in O-RAN

Cheng, Nien Fang 06 July 2023 (has links)
Fifth Generation (5G) introduces technologies that expedite the adoption of mobile networks, such as densely connected devices, ultra-fast data rate, low latency and more. With those visions in 5G and 6G in the next step, the need for a higher transmission rate and lower latency is more demanding, possibly breaking Moore’s law. With Artificial Intelligence (AI) techniques becoming mature in the past decade, optimizing resource allocation in the network has become a highly demanding problem for Mobile Network Operators (MNOs) to provide better Quality of Service (QoS) with less cost. This thesis proposes a Reinforcement Learning (RL) solution on bandwidth allocation for network slicing integration in disaggregated Open Radio Access Network (O-RAN) architecture. O-RAN redefines traditional Radio Access Network (RAN) elements into smaller components with detailed functional specifications. The concept of open modularization leads to greater potential for managing resources of different network slices. In 5G mobile networks, there are three major types of network slices, Enhanced Mobile Broadband (eMBB), Ultra-Reliable Low Latency Communications (URLLC), and Massive Machine Type Communications (mMTC). Each network slice has different features in the 5G network; therefore, the resources can be relocated depending on different needs. The virtualization of O-RAN divides the RAN into smaller function groups. This helps the network slices to divide the shared resources further down. Compared to traditional sequential signal processing, allocating dedicated resources for each network slice can improve the performance individually. In addition, shared resources can be customized statically based on the feature requirement of each slice. To further enhance the bandwidth utilization on the disaggregated O-RAN, a RL algorithm is proposed in this thesis on midhaul bandwidth allocation shared between Centralized Unit (CU) and Distributed Unit (DU). A Python-based simulator has been implemented considering several types of mobile User Equipment (UE)s for this thesis. The simulator is later integrated with the proposed Q-learning model. The RL model finds the optimization on bandwidth allocation in midhaul between Edge Open Cloud (O-Cloud)s (DUs) and Regional O-Cloud (CU). The results show up to 50% improvement in the throughput of the targeted slice, fairness to other slices, and overall bandwidth utilization on the O-Clouds. In addition, the UE QoS has a significant improvement in terms of transmission time.
3

Resource allocation and NFV placement in resource constrained MEC-enabled 5G-Networks

Fedrizzi, Riccardo 29 June 2023 (has links)
The fifth-generation (5G) of mobile communication networks are expected to support a large number of vertical industries requiring services with diverging requirements. To accommodate this, mobile networks are undergoing a significant transformation to enable a variety of services to coexist on the same infrastructure through network slicing. Additionally, the introduction of distributed user-plane and multi-access edge computing (MEC) technology allows the deployment of virtualised applications close to the network edge. The first part of this dissertation focuses on end-to-end network slice provisioning for various vertical industries with different service requirements. Two slice provisioning strategies are explored, by formulating a mixed integer linear programming (MILP) problem. Further, a genetic algorithm (GA)-based approach is proposed with the aim to improve search-space exploration. Simulation results show that the proposed approach is effective in providing near-optimal solutions while drastically reducing computational complexity. In a later stage, the study focuses on building a measurement-based digital twin (DT) for the highly heterogeneous MEC ecosystem. The DT operates as an intermediate and collaborative layer, enabling the orchestration layer to better understand network behavior before making changes to the physical network. Assisted by proper AI/ML solutions, the DT is envisioned to play a crucial role in automated network management. The study utilizes an emulated and physical test-bed to gather network key performance indicators (KPIs) and demonstrates the potential of graph neural network (GNN) in enabling closed loop automation with the help of DT. These findings offer a foundation for future research in the area of DT models and carbon footprint-aware orchestration.
4

Slice-Aware Radio Resource Management for Future Mobile Networks

Khodapanah, Behnam 05 June 2023 (has links)
The concept of network slicing has been introduced in order to enable mobile networks to accommodate multiple heterogeneous use cases that are anticipated to be served within a single physical infrastructure. The slices are end-to-end virtual networks that share the resources of a physical network, spanning the core network (CN) and the radio access network (RAN). RAN slicing can be more challenging than CN slicing as the former deals with the distribution of radio resources, where the capacity is not constant over time and is hard to extend. The main challenge in RAN slicing is to simultaneously improve multiplexing gains while assuring enough isolation between slices, meaning one of the slices cannot negatively influence other slices. In this work, a flexible and configurable framework for RAN slicing is provided, where diverse requirements of slices are taken into account, and slice management algorithms adjust the control parameters of different radio resource management (RRM) mechanisms to satisfy the slices' service level agreements (SLAs). A new entity that translates the key performance indicator (KPI) targets of the SLAs to the control parameters is introduced and is called RAN slice orchestrator. Diverse algorithms governing this entity are introduced, which range from heuristics-based to model-free methods. Besides, a protection mechanism is constructed to prevent the negative influences of slices on each other's performances. The simulation-based analysis demonstrates the feasibility of slicing the RAN with multiplexing gains and slice isolation.
5

Improving the Adaptability of the End-host : Service-aware Network Stack Tuning

Rabitsch, Alexander January 2023 (has links)
The Internet of today is very different from how it used to be. Modern networked applications are becoming increasingly diverse. Consequently, a variety of requirements must be met by the network. Efforts to make the underlying mechanisms of the Internet more flexible have therefore been made to adapt to this diversification. In this thesis, we explore how information about application requirements can be leveraged to optimize the network protocol stack of end-hosts during run-time. In addition, we improve the visibility of the network to the end-host in order to enable additional flexibility in the usage of the network's resources. We conduct tests in real-world testbeds and examine how services might be developed to optimize latency, throughput, and availability for various network traffic scenarios, including 360-degree video streaming, drone autopilots, and connected vehicles. We show how multi-connectivity, where the end-host is connected via multiple network paths simultaneously, may be used to significantly reduce latency and increase availability, while minimizing the overhead imposed on the network by carefully considering the network selection process. Furthermore, we describe an architecture that allows the user equipment and network functionality inside the 5G core network to cooperatively optimize the resource usage of the network. / The Internet of today is very different from how it used to be. Modern networked applications are becoming increasingly diverse. Consequently, a variety of requirements must be met by the network. This presents a massive challenge, since the Internet was originally designed on best-effort principle.  To address this challenge, we explore how Internet end-hosts can flexibly adapt to the needs of individual applications, by dynamically configuring the network protocol stack during run-time. In addition, we improve the visibility of the network, allowing end-hosts to better utilize the resources of the network.  We conduct tests in real-world testbeds and examine how services might be developed to optimize latency, throughput, and availability for various network traffic scenarios. We also show how multiple network paths can be used simultaneously to significantly reduce latency and increase availability, while minimizing the overhead imposed on the network. Furthermore, we describe an architecture that allows the user equipment and network functionality inside the 5G core network to cooperatively optimize the resource usage of the network. / <p>Paper II was published as a manuscript in the thesis. It is an extended version of the paper, which adds additional material that had to be cut from the original paper due to page limit restrictions.</p>
6

Adversarial Machine (Deep) Learning-basedRobustification in 5G Networks

Aminov, Mirjalol January 2023 (has links)
A significant development in wireless communication and artificial intelligence has been made possible by the combination of 5G networks with deep learning methods. This paper explores the complex interactions between these areas, concentrating on the dangers that adversarial attacks represent in the context of 5G network slicing. Multiclass classification models are created first, utilizing CNN, LSTM, and MLP architectures using a thorough three-phase process. Real adversarial attacks like FGSM, CW, BIM, and PGD are subsequently created to highlight the models' vulnerability to manipulation. The result highlights the need for strong protection measures by highlighting the upsetting potential of these attacks. The recommended defensive methods are addressed in the last stage, providing potential countermeasures to adversary threats. This study emphasizes the significance of taking into account ecological and societal implications while accepting such breakthroughs by bridging the technology and sustainability components. Integrating sustainability into the conversation becomes increasingly important as we advance the boundaries of technological innovation. By doing this, it is provided the foundation for a future that balances technical advancement with ethical progress, promoting a more robust and inclusive digital environment.
7

AI-driven admission control : with Deep Reinforcement Learning / AI-driven antagningskontroll : med Djup Förstärkningslärande

Ai, Lingling January 2021 (has links)
5G is expected to provide a high-performance and highly efficient network to prominent industry verticals with ubiquitous access to a wide range of services with orders of magnitude of improvement over 4G. Network slicing, which allocates network resources according to users’ specific requirements, is a key feature to fulfil the diversity of requirements in 5G network. However, network slicing also brings more orchestration and difficulty in monitoring and admission control. Although the problem of admission control has been extensively studied, those research take measurements for granted. Fixed high monitoring frequency can waste system resources, while low monitoring frequency (low level of observability) can lead to insufficient information for good admission control decisions. To achieve efficient admission control in 5G, we consider the impact of configurable observability, i.e. control observed information by configuring measurement frequency, is worth investigating. Generally, we believe more measurements provide more information about the monitored system, thus enabling a capable decision-maker to have better decisions. However, more measurements also bring more monitoring overhead. To study the problem of configurable observability, we can dynamically decide what measurements to monitor and their frequencies to achieve efficient admission control. In the problem of admission control with configurable observability, the objective is to minimize monitoring overhead while maintaining enough information to make proper admission control decisions. In this thesis, we propose using the Deep Reinforcement Learning (DRL) method to achieve efficient admission control in a simulated 5G end-to-end network, including core network, radio access network and four dynamic UEs. The proposed method is evaluated by comparing with baseline methods using different performance metrics, and then the results are discussed. With experiments, the proposed method demonstrates the ability to learn from interaction with the simulated environment and have good performance in admission control and used low measurement frequencies. After 11000 steps of learning, the proposed DRL agents generally achieve better performance than the threshold-based baseline agent, which takes admission decisions based on combined threshold conditions on RTT and throughput. Furthermore, the DRL agents that take non-zero measurement costs into consideration uses much lower measurement frequencies than DRL agents that take measurement costs as zero. / 5G förväntas ge ett högpresterande och högeffektivt nätverk till framstående industrivertikaler genom allmän tillgång till ett brett utbud av tjänster, med förbättringar i storleksordningar jämfört med 4G. Network slicing, som allokerar nätverksresurser enligt specifika användarkrav, är en nyckelfunktion för att uppfylla mångfalden av krav i 5G-nätverk. Network slicing kräver däremot också mer orkestrering och medför svårigheter med övervakning och tillträdeskontroll. Även om problemet med tillträdeskontroll har studerats ingående, tar de studierna mätfrekvenser för givet. Detta trots att hög övervakningsfrekvens kan slösa systemresurser, medan låg övervakningsfrekvens (låg nivå av observerbarhet) kan leda till otillräcklig information för att ta bra beslut om antagningskontroll. För att uppnå effektiv tillträdeskontroll i 5G anser vi att effekten av konfigurerbar observerbarhet, det vill säga att kontrollera observerad information genom att konfigurera mätfrekvens, är värt att undersöka. Generellt tror vi att fler mätningar ger mer information om det övervakade systemet, vilket gör det möjligt för en kompetent beslutsfattare att fatta bättre beslut. Men fler mätningar ger också högre övervakningskostnader. För att studera problemet med konfigurerbar observerbarhet kan vi dynamiskt bestämma vilka mätningar som ska övervakas och deras frekvenser för att uppnå effektiv tillträdeskontroll. I problemet med tillträdeskontroll med konfigurerbar observerbarhet är målet att minimera övervakningskostnader samtidigt som tillräckligt med information bibehålls för att fatta korrekta beslut om tillträdeskontroll. I denna avhandling föreslår vi att använda Deep Reinforcement Learning (DRL)-metoden för att uppnå effektiv tillträdeskontroll i ett simulerat 5G-änd-till-änd-nätverk, inklusive kärnnät, radioaccessnätverk och fyra dynamiska användarenheter. Den föreslagna metoden utvärderas genom att jämföra med standardmetoder som använder olika prestationsmått, varpå resultaten diskuteras. I experiment visar den föreslagna metoden förmågan att lära av interaktion med den simulerade miljön och ha god prestanda i tillträdeskontroll och använda låga mätfrekvenser. Efter 11 000 inlärningssteg uppnår de föreslagna DRL-agenterna i allmänhet bättre prestanda än den tröskelbaserade standardagenten, som fattar tillträdesbeslut baserat på kombinerade tröskelvillkor för RTT och throughput. Dessutom använder de DRL-agenter som tar hänsyn till nollskilda mätkostnader, mycket lägre mätfrekvenser än DRL-agenter som tar mätkostnaderna som noll.
8

Service Level Objective based Fairness

Chen, Wenqin January 2021 (has links)
To solve the bottleneck problem of resource utilization and user experience quality in mobile communication networks, 5G introduces network slicing to cope with the huge resource demand of users. To further improve the quality of service for users with different needs, a new fairness definition based on service level objective is introduced. On this basis, a network slicing dynamic resource scheduling strategy based on the greedy algorithm is designed, and the actual application scenarios of slicing scheduling and user scheduling are simplified into a two-layer model, namely the slicing-user model, and combined with the greedy algorithm to make the service weight value. Combine the largest slice and the user with the highest priority, and complete the matching service. The advantage of this method is various system resources can be fairly allocated according to the same proportion to users. Through the optimal combination of each slice and user, the resources of the entire system can be fairly allocated to users with different needs. Python simulation results showed that the newly proposed network slicing dynamic resource scheduling mechanism based on the greedy algorithm can meet the different needs of users and achieve short term fairness, where the users get a fair share of the resource by each missing their SLO by a similar percentage, so as to better meet the needs of users. / För att lösa flaskhalsproblemet med resursanvändning och användarupplevelsekvalitet i mobilkommunikationsnät introducerar 5G nätverksskivning för att klara användarnas enorma resursbehov. För att ytterligare förbättra servicekvaliteten för användare med olika behov införs en ny rättvisedefinition baserad på servicenivåmål. På grundval av detta utformas en dynamisk resursplaneringsstrategi för nätverksskivning baserad på den giriga algoritmen, och de faktiska applikationsscenarierna för skivningsplanering och användarschemaläggning förenklas till en tvåskiktsmodell, nämligen skivningsanvändarmodellen, och kombineras med girig algoritm för att göra tjänstens viktvärde. Kombinera den största delen och användaren med högsta prioritet och slutför motsvarande tjänst. Fördelen med denna metod är att olika systemresurser kan fördelas rättvist enligt samma andel, och genom den bästa kombinationen av varje segment och användare kan hela systemets resurser fördelas rättvist till användare med olika behov. Pythons simuleringsresultat visar att den nyligen föreslagna nätverksskärningsdynamiska resursplaneringsmekanismen baserad på den giriga algoritmen kan tillgodose användarnas olika behov och uppnå kortsiktig rättvisa där användarna får en rättvis andel av resursen genom att var och en saknar sin SLO med en liknande procentsats , för att bättre möta användarnas behov.
9

Network Slicing to Enhance Edge Computing for Automated Warehouse / Network Slicing för att förbättra Edge Computing för Automated Warehouse

Wei, Xiaoyi January 2022 (has links)
In a previous work, a distributed safety framework supported by edge computing was developed to enable real-time response of robots that collaborate with humans in the Human-Robot Collaboration (HRC) scenario. However, as the number of robots in the automated warehouse increases, the network is easier to induce the congestion. A network infrastructure that can fulfill the automated warehouse needs is therefore desired. This work develops network slicing technology in the aforementioned network infrastructure and investigates its application in the automated warehouse scenario. The goal is to improve the performance of the network through network slicing, in order that it can provide differentiated services to devices in the automated warehouse based on their needs, allowing network resources to be more efficiently allocated. With network optimization, low-latency and high reliability communication of the robot can be achieved in the automated warehouse. The performance of network slicing was compared to the scenario without this technology in the experiments. Specifically, in the standard Wireless Fidelity (Wi-Fi) network scenario without network slicing, all devices and robots will be connected to one channel to send data to the Multi-access Edge Computing (MEC) server. For the network with slicing, we divide it into three slices based on different use cases, including computers, Internet of Things (IoT) devices, and robots. Slices are created by defining multiple Service Set Identifiers (SSIDs) in a single Access Point (AP). Our results show that network slicing technology can significantly improve network performance in the automated warehouse. The network with slicing is superior to that without slicing in terms of latency at different levels of network load, which is reduced by up to 53.6%. The throughput is also increased by up to 33.5% compared to the network without slicing. Meanwhile, the network with slicing can maintain a relatively low error probability of all flows, of which the median value is 0%. It can prove that network slicing technology is beneficial for the automated warehouse network. / Begreppet samarbete mellan människa och robot (HRC) har blivit vanligt förekommande inom modern industri. I det tidigare arbetet presenteras en säkerhetsram som är utrustad med en MEC-server (Multi-access Edge Computing) för att tillhandahålla tillräcklig resurser till roboten som arbetar i det automatiserade lagret med HRC scenario. När antalet robotar i det automatiserade lagret ökar ökar, kommer nätverket att bli en flaskhals. En långsiktig, modern och robust nätverk för automatiserade lager är därför önskvärt för att anpassa sig till eventuella framtida behov. I det här projektet undersöks genomförandet av nätverksindelning i automatiserade lager med HRC-scenario. Målet är att förbättra prestanda för nätverket genom att dela upp nätverket så att det kan tillhandahålla differentierade tjänster till enheter i det automatiserade lagret baserat på utifrån deras behov, vilket gör att nätverksresurserna kan fördelas mer effektivt. Med nätverksoptimering kan kommunikation med låg latenstid och hög tillförlitlighet av roboten kan uppnås i det automatiserade lagret. Vi utförde experiment med två scenarier: standardscenarier med en Wireless Fidelity (Wi-Fi)-nätverk och Wi-Fi-nätverk med nätverksslicing. I standardscenariot för Wi-Fi-nätverk är alla enheter och robotar anslutna till en kanal för att skicka data till MEC-servern. För nätverket med slicing delar vi upp det i tre skivor baserat på olika användningsfall, inklusive datorer, IoT-enheter (Internet of Things) och robotar. Skivorna är skapas genom att definiera flera SSID:er (Service Set Identifiers) i ett enda åtkomstnät. punkt (AP). Våra resultat visar att tekniken för att dela upp nätverk kan förbättra följande avsevärt nätverksprestanda i det automatiserade lagret. Nätet med skivning är överlägset det utan skivning när det gäller latens på olika nivåer av nätverks belastning, som minskas med upp till 53,63 %. Nätet med skivning kan också fortfarande upprätthålla en relativt låg felsannolikhet för att säkerställa nätverkskvaliteten samtidigt som samtidigt som det ger hög genomströmning. Det visar att tekniken för nätverksskivning är fördelaktig för det automatiserade lagernätverket.
10

Análisis de Modelos de Negocio para Operadores de Redes 5G Soportados por Network Slicing

Moreno Cardenas, Edison Yuver 15 July 2024 (has links)
[ES] La tesis doctoral se enmarca en la línea de investigación de Economía y Regulación de las Telecomunicaciones, dentro del programa de Doctorado en Telecomunicaciones por la Universitat Politècnica de València. A lo largo del desarrollo de la tesis, se participó en los siguientes proyectos de I+D: Slicing dinámico en redes de acceso radio 5G - ATLAS (PGC2018-094151B-I00) y Evolución de la red de acceso hacia 6G para servicios masivos y de baja latencia (PID2021-123168NB-I00). Asimismo, se realizó una estancia doctoral en el IMT Atlantique en Rennes, Francia. Los resultados obtenidos se publicaron en una revista científica de ámbito internacional. En esta tesis, se estudia dos modelos de negocios y dos modelos de red para la compartición de recursos en redes de quinta generación (5G), enfocándose en servicios como Comunicaciones Ultra Confiables de Baja Latencia (URLLC), Banda Ancha Móvil Mejorada (eMBB) y Comunicaciones Masivas de Tipo Máquina (mMTC), y utilizando Network Slicing (NS). Se proponen dos escenarios. El escenario Red Compartida (SN) es una red 5G sin NS y el escenario Segmentación de red (NS) es una red 5G con NS. El escenario SN es modelado por una cola M/M/1 sin prioridad de servicio y el escenario NS es modelado por una cola M/M/1 con dos prioridades de servicio, asignando una prioridad alta al servicio URLLC por sus características con relación a la Calidad de Servicio (QoS). Además, se investigan las métricas clave de QoS como tiempo de transmisión de paquetes, sensibilidad al retardo y prioridad de servicio. Asimismo, la tesis evalúa la viabilidad económica de los modelos de negocio para operadores de redes 5G, considerando los escenarios planteados. Los modelos de negocio planteado son: el Integrado, en el cual un único operador de red ofrece ambos servicios, y el Especializado, donde dos operadores distintos ofrecen un servicio cada uno. Por otro lado, se realiza el análisis de los modelos de negocio desde el enfoque del sistema y la económica. La decisión de suscripción de los usuarios al operador se basa en su percepción de QoS y el precio, mientras que el concepto del equilibrio de Wardrop es utilizado para realizar el análisis. Asimismo, la teoría de juegos es aplicado en cada modelo de negocio para la evaluación de su viabilidad económica. La evaluación consiste en un juego de dos etapas, donde el juego se resuelve a través de la inducción hacia atrás, de manera que, se optimizan las funciones de utilidad del usuario y los beneficios de los operadores en base a la resolución de las funciones de Mejor respuesta (BR) y a diferentes valores de parámetros, consiguiendo el equilibrio de Nash. Además, se ha planteado el óptimo social, que es una situación que incorpora la participación de una entidad reguladora de servicios 5G en el mercado, quien tiene el objetivo de maximizar el bienestar social. Los resultados del óptimo social se comparan con los resultados de los dos modelos de negocio en función del bienestar social. Asimismo, se emplea conceptos de microeconomía, teoría de juegos y teoría de colas para evaluar la viabilidad económica de los diferentes modelos planteados. Esto permite entender las decisiones en equilibrio tomadas por los operadores y los usuarios, y analizar el impacto de estas decisiones en los beneficios de todos los actores involucrados. Además, se identifican los requisitos mínimos para la viabilidad de cada modelo. Los resultados muestran que, una red 5G con NS, los servicios URLLC y eMBB/mMTC pueden compartir recursos sin afectar la QoS de URLLC. Mientras que, una red 5G sin NS, la QoS de URLLC se ve afectada. Además, los operadores pueden fijar un precio más alto para URLLC debido a su QoS. Concluyendo que, la mejor opción para ofrecer los servicios URLLC y eMBB/mMTC es sobre una red 5G con NS y por un único operador. En resumen, la incorporación de NS en una red 5G, junto con un modelo de negocio Integrado, es la opción más favorable en cuanto al bienestar social. / [CA] La tesi doctoral s'emmarca en la línia d'investigació d'Economia i Regulació de les Telecomunicacions, dins del programa de Doctorat en Telecomunicacions per la Universitat Politècnica de València. Al llarg del desenvolupament de la tesi, es va participar en els següents projectes d'I+D: Slicing dinàmic en xarxes d'accés radie 5G - ATLES (PGC2018-094151B-I00) i Evolució de la xarxa d'accés cap a 6G per a servicis massius i de baixa latència (PID2021-123168NB-I00). Així mateix, es va realitzar una estada doctoral en el IMT Atlantique en Rennes, França. Els resultats obtinguts es van publicar en una revista científica d'àmbit internacional. En esta tesi, s'estudia dos models de negocis i dos models de xarxa per a la compartició de recursos en xarxes de quinta generació (5G), enfocant-se en servicis com a Comunicacions Ultres De confiança de Baixa Latència (URLLC), Banda Ampla Mòbil Millorada (eMBB) i Comunicacions Massives de Tipus Màquina (mMTC), i utilitzant Network Slicing (NS). Es proposen dos escenaris. L'escenari Xarxa Compartida (SN) és una xarxa 5G sense NS i l'escenari Segmentació de xarxa (NS) és una xarxa 5G amb NS. L'escenari SN és modelat per una cua M/M/1 sense prioritat de servici i l'escenari NS és modelat per una cua M/M/1 amb dos prioritats de servici, assignant una prioritat alta al servici URLLC per les seues característiques en relació amb la Qualitat de Servici (QoS). A més, s'investiguen les mètriques clau de QoS com a temps de transmissió de paquets, sensibilitat al retard i prioritat de servici. Així mateix, la tesi avalua la viabilitat econòmica dels models de negoci per a operadors de xarxes 5G, considerant els escenaris plantejats. Els models de negoci plantejat són: l'Integrat, en el qual un únic operador de xarxa oferix tots dos servicis, i l'Especialitzat, on dos operadors diferents oferixen un servici cadascun. D'altra banda, es realitza l'anàlisi dels models de negoci des de l'enfocament del sistema i l'econòmica. La decisió de subscripció dels usuaris a l'operador es basa en la seua percepció de QoS i el preu, mentres que el concepte de l'equilibri de Wardrop és utilitzat per a realitzar l'anàlisi. Així mateix, la teoria de jocs és aplicat en cada model de negoci per a l'avaluació de la seua viabilitat econòmica. L'avaluació consistix en un joc de dos etapes, on el joc es resol a través de la inducció cap arrere, de manera que, s'optimitzen les funcions d'utilitat de l'usuari i els beneficis dels operadors sobre la base de la resolució de les funcions de Millor resposta (BR) i a diferents valors de paràmetres, aconseguint l'equilibri de Nash. A més, s'ha plantejat l'òptim social, que és una situació que incorpora la participació d'una entitat reguladora de servicis 5G en el mercat, qui té l'objectiu de maximitzar el benestar social. Els resultats de l'òptim social es comparen amb els resultats dels dos models de negoci en funció del benestar social. Així mateix, s'empra conceptes de microeconomia, teoria de jocs i teoria de cues per a avaluar la viabilitat econòmica dels diferents models plantejats. Això permet entendre les decisions en equilibri preses pels operadors i els usuaris, i analitzar l'impacte d'estes decisions en els beneficis de tots els actors involucrats. A més, s'identifiquen els requisits mínims per a la viabilitat de cada model. Els resultats mostren que, una xarxa 5G amb NS, els servicis URLLC i eMBB/mMTC poden compartir recursos sense afectar la QoS de URLLC. Mentres que, una xarxa 5G sense NS, la QoS de URLLC es veu afectada. A més, els operadors poden fixar un preu més alt per a URLLC a causa del seu QoS. Concloent que, la millor opció per a oferir els servicis URLLC i eMBB/mMTC és sobre una xarxa 5G amb NS i per un únic operador. En resum, la incorporació de NS en una xarxa 5G, juntament amb un model de negoci Integrat, és l'opció més favorable quant al benestar social. / [EN] The doctoral thesis is framed within the research line of Economics and Regulation of Telecommunications within the PhD program in Telecommunications at the Universitat Politècnica de València. Throughout the development of the thesis, we participated in the following R&D projects: Dynamic Slicing in 5G radio access networks - ATLAS (PGC2018-094151B-I00) and Evolution of the access network towards 6G for massive and low latency services (PID2021-123168NB-I00). A doctoral stay at the IMT Atlantique in Rennes, France, was also carried out. The results obtained were published in an international scientific journal. In this thesis, two business models and two network models for resource sharing in fifth-generation (5G) networks are studied, focusing on services such as Ultra Reliable Low Latency Communications (URLLC), Enhanced Mobile Broadband (eMBB), and Massive Machine Type Communications (mMTC), and using Network Slicing (NS). Two scenarios are proposed. The Network Sharing (SN) scenario is a 5G network without NS, and the Network Slicing (NS) scenario is a 5G network with NS. The SN scenario is modeled by an M/M/1 queue with no service priority, and the NS scenario is modeled by an M/M/1 queue with two service priorities, assigning a high priority to the URLLC service for its Quality of Service (QoS) characteristics. Furthermore, key QoS metrics such as packet transmission time, delay sensitivity, and service priority are investigated. Furthermore, the thesis evaluates the economic viability of business models for 5G network operators, considering the scenarios proposed. The business models proposed are Integrated, in which a single network operator offers both services and Specialised, where two different operators offer one service each. On the other hand, the business models are analyzed from a system and economic perspective. The users' subscription decision to the operator is based on their perception of QoS and price, while the Wardrop equilibrium concept is used to perform the analysis. Furthermore, game theory is applied to each business model for the evaluation of its economic viability. The evaluation consists of a two-stage game, where the game is solved through backward induction so that the user's utility functions and the operators' profits are optimized based on the resolution of the Best Response (BR) functions and different parameter values, achieving the Nash equilibrium. In addition, the social optimum has been considered, which is a situation that incorporates the participation of a 5G service regulator in the market, who has the objective of maximizing social welfare. The results of the social optimum are compared with the results of the two business models in terms of social welfare. Furthermore, concepts from microeconomics, game theory, and queueing theory are used to assess the economic viability of the different models proposed. This allows us to understand the equilibrium decisions made by operators and users and to analyze the impact of these decisions on the benefits of all the actors involved. In addition, the minimum requirements for the viability of each model are identified. The results show that a 5G network with NS, URLLC, and eMBB/mMTC services can share resources without affecting URLLC QoS. On the other hand, in a 5G network without NS, the QoS of URLLC is affected. In addition, operators can set a higher price for URLLC due to its QoS. Conclusion: The best option to offer URLLC and eMBB/mMTC services is over a 5G network with NS and by a single operator. In summary, the incorporation of NS in a 5G network, together with an Integrated business model, is the most favorable option in terms of social welfare. / Moreno Cardenas, EY. (2024). Análisis de Modelos de Negocio para Operadores de Redes 5G Soportados por Network Slicing [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/206184

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