Entendre els fonaments de la tecnologia i conèixer com ens impactarà el seu desplegament. Vam descobrir les diferents aplicacions que tindrà el 5G en el nostre dia a dia i el valor que aportarà
This is the second part of my 5G project which consists of the architecture structure of 5G. What all it consists of, what all technologies it uses, what all layers it contain etc.
We are looking at the future of technology that has the structure of Nanocore, beneficial for future applications.
LTE, LTE A, and LTE A Pro Migration to 5G Training : Tonex TrainingBryan Len
LTE, LTE-A, and LTE-A Pro Migration to 5G Training covers LTE, LTE-Advanced, LTE-Advanced Pro, features and enhancements and migration towards 5G. Other topics include: 5G NR, Air Interface Architecture, 5G Core (5GC) Architecture, Nodes, Interfaces, and Operation.
Topics Include:
5GC Overview
5G Technology Overview
5G System Survey
5G Architecture and Interfaces
5G Network Services
5G-NR Architecture, Interfaces, Protocols and Operations
5G-NR Signaling
5G Core (5GC) Architecture, Interfaces, Protocols and Operations
Multi-Access Edge Computing (MEC)
Advanced LPWA for IoT
5G Signaling and Operations
5G Protocol and Architecture
5GC Network Solutions
5G Network Design and Optimization
5G Network Roll-Out
5G Capacity Planning
5G For Non-Engineers and Managers
5G RAN Signaling
5G RF Engineering
5G RF Planning
Learning Objectives:
After completing this course, the student will be able to:
Describe the evolution from LTE/LTE-A and LTE-A Pro to 5G
Summarize LTE-A pro architecture enhancements towards 5G
Describe the fundamentals of 5G networks
Illustrate the architecture of the 5G network including 5G NR,5GC
Describe Enhanced Mobile Broadband (eMBB), Massive Machine Type (mMTC) Communications and Ultra-Reliable and Low Latency Communications (URLLC) features in 5G
Identify key 5G network functions, interfaces, protocols and interworking elements
Describe how the 5G NR works
Describe 5GC network functions and interfaces
Compare 5G Service Based Architecture vs. Reference Point Architecture
Describe ingratiation paths to 5G
Courses Material, Tools and Guides, Outlines:
Evolution from LTE/LTE-A Pro to 5G
Overview of 5G Network Services
5G Radio and Core Network Architecture
Network Slicing in 5G
Architecture Evolution from LTE/LTE-A and LTE-A Pro to 5G NR
Cloud and Open RAN Architectures
Control and User Plane Architecture and Bearer Types
Introduction 5G Core Network (5GC)
Overview of 5G Core Network (5GC) Network Entities
5G Network Deployment and Migration Paths
Case Studies
Request more information about LTE, LTE-A, and LTE-A Pro Migration to 5G Training. Visit Tonex.com link below
https://www.tonex.com/training-courses/lte-lte-a-and-lte-a-pro-migration-to-5g-training/
Entendre els fonaments de la tecnologia i conèixer com ens impactarà el seu desplegament. Vam descobrir les diferents aplicacions que tindrà el 5G en el nostre dia a dia i el valor que aportarà
This is the second part of my 5G project which consists of the architecture structure of 5G. What all it consists of, what all technologies it uses, what all layers it contain etc.
We are looking at the future of technology that has the structure of Nanocore, beneficial for future applications.
LTE, LTE A, and LTE A Pro Migration to 5G Training : Tonex TrainingBryan Len
LTE, LTE-A, and LTE-A Pro Migration to 5G Training covers LTE, LTE-Advanced, LTE-Advanced Pro, features and enhancements and migration towards 5G. Other topics include: 5G NR, Air Interface Architecture, 5G Core (5GC) Architecture, Nodes, Interfaces, and Operation.
Topics Include:
5GC Overview
5G Technology Overview
5G System Survey
5G Architecture and Interfaces
5G Network Services
5G-NR Architecture, Interfaces, Protocols and Operations
5G-NR Signaling
5G Core (5GC) Architecture, Interfaces, Protocols and Operations
Multi-Access Edge Computing (MEC)
Advanced LPWA for IoT
5G Signaling and Operations
5G Protocol and Architecture
5GC Network Solutions
5G Network Design and Optimization
5G Network Roll-Out
5G Capacity Planning
5G For Non-Engineers and Managers
5G RAN Signaling
5G RF Engineering
5G RF Planning
Learning Objectives:
After completing this course, the student will be able to:
Describe the evolution from LTE/LTE-A and LTE-A Pro to 5G
Summarize LTE-A pro architecture enhancements towards 5G
Describe the fundamentals of 5G networks
Illustrate the architecture of the 5G network including 5G NR,5GC
Describe Enhanced Mobile Broadband (eMBB), Massive Machine Type (mMTC) Communications and Ultra-Reliable and Low Latency Communications (URLLC) features in 5G
Identify key 5G network functions, interfaces, protocols and interworking elements
Describe how the 5G NR works
Describe 5GC network functions and interfaces
Compare 5G Service Based Architecture vs. Reference Point Architecture
Describe ingratiation paths to 5G
Courses Material, Tools and Guides, Outlines:
Evolution from LTE/LTE-A Pro to 5G
Overview of 5G Network Services
5G Radio and Core Network Architecture
Network Slicing in 5G
Architecture Evolution from LTE/LTE-A and LTE-A Pro to 5G NR
Cloud and Open RAN Architectures
Control and User Plane Architecture and Bearer Types
Introduction 5G Core Network (5GC)
Overview of 5G Core Network (5GC) Network Entities
5G Network Deployment and Migration Paths
Case Studies
Request more information about LTE, LTE-A, and LTE-A Pro Migration to 5G Training. Visit Tonex.com link below
https://www.tonex.com/training-courses/lte-lte-a-and-lte-a-pro-migration-to-5g-training/
Performance evaluation of software-defined networking controllers in wired an...TELKOMNIKA JOURNAL
Traditional networking solutions are unable to meet modern computing needs due to the expanding popularity of the internet, which requires increased agility and flexibility. To meet these objectives, software-defined networking (SDN) arises. A controller is a major element that will determine if SDN succeeds or fails. Various current SDN controllers in many sectors must be evaluated and compared. The performance of two well-known SDN controllers, POX and Ryu, is evaluated in this research. We used the Mininet-WiFi emulator to implement our work and the distributed internet traffic generator (D-ITG) to assess the aforementioned controllers using delay, jitter, packet loss, and throughput metrics. What is new in our research is the study of network performance in two different types of transmission media: wired and wireless. The speed of the wired medium was chosen to be fast ethernet, which was not previously studied. In addition, the size of the packet was varied among 128, 256, 512, and 1,024 bytes. The comparison was performed on three topologies (single, linear, and tree). The experimental results showed that Ryu offers significantly lower latency, jitter, and packet loss than POX in most scenarios. Also, the Ryu controller has higher throughput than POX, especially on wireless networks.
Towards achieving-high-performance-in-5g-mobile-packet-cores-user-plane-functionEiko Seidel
White Paper Intel SK Telekom
This paper presents the architecture for a user plane function (UPF) in the mobile packet core (MPC) targeting 5G deployments.
Network slicing is a method of creating multiple unique logical and virtual networks on a common multi-domain infrastructure.
A different approach to view is that network slicing overlays multiple virtual networks on a shared network. Each part of the network can have its own logical topology, security rules and performance characteristics-within the limits imposed by the basic physical network.
Network slicing is a key function of 5G.
5G network slicing is a virtual network architecture that belongs to the same family as Software-defined Networking (SDN) and Network Function Virtualization (NFV).
The benefits of network slicing are:
It can help network operators reduce expenditure (OPEX) and capital expenditure (CAPEX).
It greatly improves the operational efficiency and time to market for delivering 5G network services.
A single network can be used to provide various services according to user needs and various use cases.
Network operators can allocate the proper amount of required resources as per network slice.
It overcomes all the shortcomings of the most popular QoS solution "DiffServ".
Fundamentals of 5G Network Slicing Training by Tonex
Fundamentals of 5G Network Slicing Training focuses on key principles, architecture and implementation of 5G network slicing.
Participants discover the way to effectively use network slicing across 5G core, RAN and transport networks. you'll also find out how network slicing is one among key components that provide 5G operation.
Audience:
Software Engineers
Network Design Engineers
Managers
Product management, marketing, planning, operations and employees with little or no experience in 5G or network slicing.
People who have 5G network experience but have never received any formal training on network slicing.
Learning Objectives:
How to implement network slicing in 5G networks
How to lay the foundation for 5G network slicing monetization
How to plan and design the lifecycle management of network slicing
How to implement network slicing and be able to support various services with specific performance or control requirements on a common network platform
Summary of 5G use cases and applications
5G network overview
How to implement operational KPIs on slice/service instantiation, termination, activation, deactivation, usage events, dynamic resource consumption based on slice/service/network functions, and performance and analysis events based on the set of network slice performance indicators
Course Agenda:
Overview of 5G Networks
Digital Transformation and Network Slicing
Network Slicing Deployment
Learn More;
https://www.tonex.com/training-courses/fundamentals-of-5g-network-slicing/
Artigo: Multilayer Networks: An Architecture FrameworkDiogo Oliveira
Artigo bem bacana do professor Nasir Ghani (University of South Florida) que explica o que são redes Multicamadas. O objetivo do artigo não é explicar a multicamadas, mas apresentar um framework. Porém através das explicações e do cenário a compreensão do termo é facilitada.
International Journal of Engineering Research and Applications (IJERA) is an open access online peer reviewed international journal that publishes research and review articles in the fields of Computer Science, Neural Networks, Electrical Engineering, Software Engineering, Information Technology, Mechanical Engineering, Chemical Engineering, Plastic Engineering, Food Technology, Textile Engineering, Nano Technology & science, Power Electronics, Electronics & Communication Engineering, Computational mathematics, Image processing, Civil Engineering, Structural Engineering, Environmental Engineering, VLSI Testing & Low Power VLSI Design etc.
Last update: Feb 7, 2021
5G broadband began to be promoted throughout the United States, it not only brought users a faster Internet, but also brought a new technical architecture designed to further support 5G networks.
As operators around the world are looking for solutions to cope with the growing demand for mobile data, it is necessary to develop 5G technology.
One of those architectures is named device-to-device (D2D) communications, which refers to the communication between devices, which may be cellphones or vehicles. this system opens new device-centric communication that always requires no direct communication with the network infrastructure.
This is good because D2D architecture is predicted to unravel a minimum of a part of the network capacity issue as 5G promises more devices to be connected in faster, more reliable networks.
To understand the new 5G technology, the important point is that it does not only involve faster smartphones. In fact, technologists now call 5G the post-smartphone era.
Higher speeds and lower latency will enable new experiences that require continuous communication between augmented reality and virtual reality, connected cars, smart homes, and machines without lag.
Tonex provided 5G Network Architecture, Planning and Design
Tonex training introduced 5G technology, architecture and protocols. Also discussed 5G air interface and core network technologies and solutions. The course includes investigations of traffic cases and solutions, deployments and products. Covers 3GPP and IMT-2020 methods.
Learning Targets:
Explain the key 5G Principles, Services and Technical aspects
Explain the aim of implementing 5G within the existing mobile ecosystem
Describe a number of the 5G Use Cases and Applications: 3GPP and ITU 5G Use Cases (eMBB, URLLC and mMTC)
List 5G Network Features including: functions, nodes and elements, interfaces, reference points, basic operational procedures and architectural choices
Describe the overall 5G specification
Compare and contrast 5G system with traditional LTE, LTE-A and LTE-A Pro systems (3GPP version)
List and explain 5G RAN and core network architecture
Explain 5G access
Describe the 5G system engineering (access network, 5G core) method
Describe the use of NFV/SDN and network slicing in 5G systems
Learn about 5G radio access networks including 5G New Radio (NR)
Audience:
Engineers
Managers
Marketing and operation personnel
Anyone who want to learn 5G systems including 5G Radio Access Network (RAN), 5G New Radio (NR), 5G core and integration with LTE/LTE-A and LTE-A Pro
Course Outline:
Introduction to 5G Mobile Communication
Key Principles of 5G Systems
5G System Architecture
3GPP 5G System Architecture
5G New Radio (NR)
For More Information:
https://www.tonex.com/5g-training-education-5g-wireless/
Mobility Management For Next Generation NetworksGreen Packet
Increasingly, operators worldwide will be faced with a similar challenge of managing data congestion over multiple access networks. With networks evolving into LTE, operators would need to carefully assess the technology fit into integrating complementary nature of multiple access networks into an all-IP flat architecture. An all IP flat architecture helps to tie heterogeneous access networks that devices can attach to access end-user services. Communication devices today are able to connect with more than one type of wireless technologies to the “web of things”. An end-user will connect to a Wi-Fi hotspot, if within range. When moving away from range, the communication link is handover to for example, UMTS. The motivation of inter-working lies in marrying the diverse strengths of each communication technology. High-bandwidth data communication inherent in WLAN lacks mobility. Conversely, cellular technologies such as UMTS succeed in highly mobile environments, but limited in bandwidth. Although cellular networks are evolving from today’s 3G to LTE that brings promise of capacity leaps (by nearly 4 times), the overall data growth projection will outpace LTE deployments and fill up very quickly.
The immediate need to curtail congested network and effectively manage mobility is imminent to accommodate the data traffic on their networks. The impact of inter-mobility between inter access technology together with various types of mobility support including 3GPP legacy network and non 3GPP is necessary to provide a target low-latency, higher data-rate, all-IP core network capable of supporting real-time packet services. Some of the available IP mobility protocols lack sufficient control to the network to optimize the handover process and do not handle well with slow connection setups of some wireless technologies. This paper highlights the potential approaches of bringing together mobility technologies that are available and how these approaches contribute to resolve operator concerns in deployment of services and combating congestion, access technology integration and evolution to LTE from legacy 3GPP networks.
Slovakian Internet Exchange improves platform to make customer experience potent differentiator by leveraging on Cisco Cloud architecture and the Fabric Path solution
Francesca Gottschalk - How can education support child empowerment.pptxEduSkills OECD
Francesca Gottschalk from the OECD’s Centre for Educational Research and Innovation presents at the Ask an Expert Webinar: How can education support child empowerment?
Unit 8 - Information and Communication Technology (Paper I).pdfThiyagu K
This slides describes the basic concepts of ICT, basics of Email, Emerging Technology and Digital Initiatives in Education. This presentations aligns with the UGC Paper I syllabus.
Performance evaluation of software-defined networking controllers in wired an...TELKOMNIKA JOURNAL
Traditional networking solutions are unable to meet modern computing needs due to the expanding popularity of the internet, which requires increased agility and flexibility. To meet these objectives, software-defined networking (SDN) arises. A controller is a major element that will determine if SDN succeeds or fails. Various current SDN controllers in many sectors must be evaluated and compared. The performance of two well-known SDN controllers, POX and Ryu, is evaluated in this research. We used the Mininet-WiFi emulator to implement our work and the distributed internet traffic generator (D-ITG) to assess the aforementioned controllers using delay, jitter, packet loss, and throughput metrics. What is new in our research is the study of network performance in two different types of transmission media: wired and wireless. The speed of the wired medium was chosen to be fast ethernet, which was not previously studied. In addition, the size of the packet was varied among 128, 256, 512, and 1,024 bytes. The comparison was performed on three topologies (single, linear, and tree). The experimental results showed that Ryu offers significantly lower latency, jitter, and packet loss than POX in most scenarios. Also, the Ryu controller has higher throughput than POX, especially on wireless networks.
Towards achieving-high-performance-in-5g-mobile-packet-cores-user-plane-functionEiko Seidel
White Paper Intel SK Telekom
This paper presents the architecture for a user plane function (UPF) in the mobile packet core (MPC) targeting 5G deployments.
Network slicing is a method of creating multiple unique logical and virtual networks on a common multi-domain infrastructure.
A different approach to view is that network slicing overlays multiple virtual networks on a shared network. Each part of the network can have its own logical topology, security rules and performance characteristics-within the limits imposed by the basic physical network.
Network slicing is a key function of 5G.
5G network slicing is a virtual network architecture that belongs to the same family as Software-defined Networking (SDN) and Network Function Virtualization (NFV).
The benefits of network slicing are:
It can help network operators reduce expenditure (OPEX) and capital expenditure (CAPEX).
It greatly improves the operational efficiency and time to market for delivering 5G network services.
A single network can be used to provide various services according to user needs and various use cases.
Network operators can allocate the proper amount of required resources as per network slice.
It overcomes all the shortcomings of the most popular QoS solution "DiffServ".
Fundamentals of 5G Network Slicing Training by Tonex
Fundamentals of 5G Network Slicing Training focuses on key principles, architecture and implementation of 5G network slicing.
Participants discover the way to effectively use network slicing across 5G core, RAN and transport networks. you'll also find out how network slicing is one among key components that provide 5G operation.
Audience:
Software Engineers
Network Design Engineers
Managers
Product management, marketing, planning, operations and employees with little or no experience in 5G or network slicing.
People who have 5G network experience but have never received any formal training on network slicing.
Learning Objectives:
How to implement network slicing in 5G networks
How to lay the foundation for 5G network slicing monetization
How to plan and design the lifecycle management of network slicing
How to implement network slicing and be able to support various services with specific performance or control requirements on a common network platform
Summary of 5G use cases and applications
5G network overview
How to implement operational KPIs on slice/service instantiation, termination, activation, deactivation, usage events, dynamic resource consumption based on slice/service/network functions, and performance and analysis events based on the set of network slice performance indicators
Course Agenda:
Overview of 5G Networks
Digital Transformation and Network Slicing
Network Slicing Deployment
Learn More;
https://www.tonex.com/training-courses/fundamentals-of-5g-network-slicing/
Artigo: Multilayer Networks: An Architecture FrameworkDiogo Oliveira
Artigo bem bacana do professor Nasir Ghani (University of South Florida) que explica o que são redes Multicamadas. O objetivo do artigo não é explicar a multicamadas, mas apresentar um framework. Porém através das explicações e do cenário a compreensão do termo é facilitada.
International Journal of Engineering Research and Applications (IJERA) is an open access online peer reviewed international journal that publishes research and review articles in the fields of Computer Science, Neural Networks, Electrical Engineering, Software Engineering, Information Technology, Mechanical Engineering, Chemical Engineering, Plastic Engineering, Food Technology, Textile Engineering, Nano Technology & science, Power Electronics, Electronics & Communication Engineering, Computational mathematics, Image processing, Civil Engineering, Structural Engineering, Environmental Engineering, VLSI Testing & Low Power VLSI Design etc.
Last update: Feb 7, 2021
5G broadband began to be promoted throughout the United States, it not only brought users a faster Internet, but also brought a new technical architecture designed to further support 5G networks.
As operators around the world are looking for solutions to cope with the growing demand for mobile data, it is necessary to develop 5G technology.
One of those architectures is named device-to-device (D2D) communications, which refers to the communication between devices, which may be cellphones or vehicles. this system opens new device-centric communication that always requires no direct communication with the network infrastructure.
This is good because D2D architecture is predicted to unravel a minimum of a part of the network capacity issue as 5G promises more devices to be connected in faster, more reliable networks.
To understand the new 5G technology, the important point is that it does not only involve faster smartphones. In fact, technologists now call 5G the post-smartphone era.
Higher speeds and lower latency will enable new experiences that require continuous communication between augmented reality and virtual reality, connected cars, smart homes, and machines without lag.
Tonex provided 5G Network Architecture, Planning and Design
Tonex training introduced 5G technology, architecture and protocols. Also discussed 5G air interface and core network technologies and solutions. The course includes investigations of traffic cases and solutions, deployments and products. Covers 3GPP and IMT-2020 methods.
Learning Targets:
Explain the key 5G Principles, Services and Technical aspects
Explain the aim of implementing 5G within the existing mobile ecosystem
Describe a number of the 5G Use Cases and Applications: 3GPP and ITU 5G Use Cases (eMBB, URLLC and mMTC)
List 5G Network Features including: functions, nodes and elements, interfaces, reference points, basic operational procedures and architectural choices
Describe the overall 5G specification
Compare and contrast 5G system with traditional LTE, LTE-A and LTE-A Pro systems (3GPP version)
List and explain 5G RAN and core network architecture
Explain 5G access
Describe the 5G system engineering (access network, 5G core) method
Describe the use of NFV/SDN and network slicing in 5G systems
Learn about 5G radio access networks including 5G New Radio (NR)
Audience:
Engineers
Managers
Marketing and operation personnel
Anyone who want to learn 5G systems including 5G Radio Access Network (RAN), 5G New Radio (NR), 5G core and integration with LTE/LTE-A and LTE-A Pro
Course Outline:
Introduction to 5G Mobile Communication
Key Principles of 5G Systems
5G System Architecture
3GPP 5G System Architecture
5G New Radio (NR)
For More Information:
https://www.tonex.com/5g-training-education-5g-wireless/
Mobility Management For Next Generation NetworksGreen Packet
Increasingly, operators worldwide will be faced with a similar challenge of managing data congestion over multiple access networks. With networks evolving into LTE, operators would need to carefully assess the technology fit into integrating complementary nature of multiple access networks into an all-IP flat architecture. An all IP flat architecture helps to tie heterogeneous access networks that devices can attach to access end-user services. Communication devices today are able to connect with more than one type of wireless technologies to the “web of things”. An end-user will connect to a Wi-Fi hotspot, if within range. When moving away from range, the communication link is handover to for example, UMTS. The motivation of inter-working lies in marrying the diverse strengths of each communication technology. High-bandwidth data communication inherent in WLAN lacks mobility. Conversely, cellular technologies such as UMTS succeed in highly mobile environments, but limited in bandwidth. Although cellular networks are evolving from today’s 3G to LTE that brings promise of capacity leaps (by nearly 4 times), the overall data growth projection will outpace LTE deployments and fill up very quickly.
The immediate need to curtail congested network and effectively manage mobility is imminent to accommodate the data traffic on their networks. The impact of inter-mobility between inter access technology together with various types of mobility support including 3GPP legacy network and non 3GPP is necessary to provide a target low-latency, higher data-rate, all-IP core network capable of supporting real-time packet services. Some of the available IP mobility protocols lack sufficient control to the network to optimize the handover process and do not handle well with slow connection setups of some wireless technologies. This paper highlights the potential approaches of bringing together mobility technologies that are available and how these approaches contribute to resolve operator concerns in deployment of services and combating congestion, access technology integration and evolution to LTE from legacy 3GPP networks.
Slovakian Internet Exchange improves platform to make customer experience potent differentiator by leveraging on Cisco Cloud architecture and the Fabric Path solution
Francesca Gottschalk - How can education support child empowerment.pptxEduSkills OECD
Francesca Gottschalk from the OECD’s Centre for Educational Research and Innovation presents at the Ask an Expert Webinar: How can education support child empowerment?
Unit 8 - Information and Communication Technology (Paper I).pdfThiyagu K
This slides describes the basic concepts of ICT, basics of Email, Emerging Technology and Digital Initiatives in Education. This presentations aligns with the UGC Paper I syllabus.
Instructions for Submissions thorugh G- Classroom.pptxJheel Barad
This presentation provides a briefing on how to upload submissions and documents in Google Classroom. It was prepared as part of an orientation for new Sainik School in-service teacher trainees. As a training officer, my goal is to ensure that you are comfortable and proficient with this essential tool for managing assignments and fostering student engagement.
Welcome to TechSoup New Member Orientation and Q&A (May 2024).pdfTechSoup
In this webinar you will learn how your organization can access TechSoup's wide variety of product discount and donation programs. From hardware to software, we'll give you a tour of the tools available to help your nonprofit with productivity, collaboration, financial management, donor tracking, security, and more.
Honest Reviews of Tim Han LMA Course Program.pptxtimhan337
Personal development courses are widely available today, with each one promising life-changing outcomes. Tim Han’s Life Mastery Achievers (LMA) Course has drawn a lot of interest. In addition to offering my frank assessment of Success Insider’s LMA Course, this piece examines the course’s effects via a variety of Tim Han LMA course reviews and Success Insider comments.
How to Make a Field invisible in Odoo 17Celine George
It is possible to hide or invisible some fields in odoo. Commonly using “invisible” attribute in the field definition to invisible the fields. This slide will show how to make a field invisible in odoo 17.
Macroeconomics- Movie Location
This will be used as part of your Personal Professional Portfolio once graded.
Objective:
Prepare a presentation or a paper using research, basic comparative analysis, data organization and application of economic information. You will make an informed assessment of an economic climate outside of the United States to accomplish an entertainment industry objective.
Read| The latest issue of The Challenger is here! We are thrilled to announce that our school paper has qualified for the NATIONAL SCHOOLS PRESS CONFERENCE (NSPC) 2024. Thank you for your unwavering support and trust. Dive into the stories that made us stand out!
1. QOS MANAGEMENT AND
FLEXIBLE TRAFFIC DETECTION
ARCHITECTURE FOR 5G MOBILE
NETWORKS
NADHIF MUHAMMAD REKOPUTRA
M1
2. PROBLEM
5G need to provide services with the highest
Quality of Service (QoS) attributes such as
• Ultra-low latency
• Ultra-reliable communication
• High data rates
• High user mobility experience
3. GOAL
Learn about 5G Architecture that combines Network
Function Virtualization (NFV) and Software-Defined
Networking (SDN), along with the shift of processes
to the edge of the network
Learn about how incorporating Multiprotocol Label
Switching (MPLS) in the mobile data plane could
achive that
4. REFERENCE
• Author
López Rodríguez, F.; Silva Dias, U.; Campelo, D.R.; Oliveira
Albuquerque, R.; Lim, S.-J.; García Villalba, L.J.
• Title
QoS Management and Flexible Traffic Detection Architecture for 5G
Mobile Networks. Sensors 2019, 19, 1335.
5. LIST OF TASK
• Week 1 and 2
Learn about the general architecture that uses openflow switches to
separate control and data plane
Expected Output : Draw the architecture and explain the architecture in
hackmd
• Week 3 and 4
Learn about how Multiprocol Label Switching work on the data plane
Expected Output : Draw the architecture and explain the architecture in
hackmd
6. LIST OF TASK
• Week 5 and 6
Learn about the proposed architecture to route the traffic
Expected Output : Draw the concept and explain it in hackmd
• Week 7 and 8
Learn about how the qos traffic routing
Expected Output : Draw the concept and explain it in hackmd
