CTU FEE Moodle
Advaced Network Technologies
B232 - Summer 23/24
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Advaced Network Technologies - A0M32PST
| Credits | 5 |
| Semesters | Summer |
| Completion | Assessment + Examination |
| Language of teaching | Czech |
| Extent of teaching | 2+2L |
Annotation
Subject Advanced Network Technologies expands students' knowledge of modern network technologies. The course is practically oriented and focused on explaining the function of advanced network protocols as used in modern data networks of today and tomorrow. Students will gain practical experience with the issues like Internet routing, software-defined networks, multicast routing, IPv6, and MPLS networks. Part of the course is also devoted to a detailed explanation of transport protocols TCP/UDP and a manner in which software applications can access transportation services of TCP/IP data networks.
Study targets
The aim of this study is to familiarize students with additional issues in the field of data networks that go beyond the basic knowledge already acquired in other network-oriented subjects. The course is composed so as to provide students with a much larger laboratory time/space for detailed individual exploration of focused range of problems in data networks. Subject is not too much about a width, but rather goes into a depth of issues presented.
Course outlines
1. Introduction. Review of basic concepts.
2.Review of basic routing principles, OSPF routing protocol.
3.Practical projects, data networks and their simulation in OMNeT + program.
4.Software defined networks (SDN) and their use in practice - the latest hot topics from the field of data networking. Network Function Virtualization (NFV).
5.Application space, transport protocols and their usage, sockets.
6.TCP and its functions, principles of congestion in the network, AIMD, TCP congestion avoidance
7. Internet as inter-ISP network . Interconnection ISPs - transit, peering, IXP. Understanding the function of the border routing protocol (BGPv4).
8. Affecting distribution of ISP input/output data streams using BGPv4 - attributes, weight, AS path, local preference.
9. IP multicast. Resource-oriented multicast distribution tree. Shared multicast tree.
10.Protocol Independent Multicast, sparse and dense mode (PIM-SM, DM)
11. MPLS network and its comparison with conventional IP routed ones.
12. MPLS label distribution protocol and its deployment in MPLS networks.
13. MPLS services. Architecture of MPLS VPN network. IPv6 addressing, IPv6 routing.
14. Cooperation between IPv4 and IPv6.
2.Review of basic routing principles, OSPF routing protocol.
3.Practical projects, data networks and their simulation in OMNeT + program.
4.Software defined networks (SDN) and their use in practice - the latest hot topics from the field of data networking. Network Function Virtualization (NFV).
5.Application space, transport protocols and their usage, sockets.
6.TCP and its functions, principles of congestion in the network, AIMD, TCP congestion avoidance
7. Internet as inter-ISP network . Interconnection ISPs - transit, peering, IXP. Understanding the function of the border routing protocol (BGPv4).
8. Affecting distribution of ISP input/output data streams using BGPv4 - attributes, weight, AS path, local preference.
9. IP multicast. Resource-oriented multicast distribution tree. Shared multicast tree.
10.Protocol Independent Multicast, sparse and dense mode (PIM-SM, DM)
11. MPLS network and its comparison with conventional IP routed ones.
12. MPLS label distribution protocol and its deployment in MPLS networks.
13. MPLS services. Architecture of MPLS VPN network. IPv6 addressing, IPv6 routing.
14. Cooperation between IPv4 and IPv6.
Exercises outlines
1.project assignment and introduction into lesson
2.programming principles of routers in the network with the BGP Protocol
3.network implementation with BGP protocol in the laboratory
4.network configuration of multicast routing protocol
5.network implementation of multicast routing protocols like PIM-DM and SM
6.configuration of IPv6 networks
7.test #1
8.building and testing networks with IPv6
9.Analysis of virtual networks (VPN) in MPLS environment
10.building networks with virtual VPN support in a MPLS environment
11.On TCP throughput
12.examples of measuring throughput of the TCP protocol in different types of networks
13.test#2
14.Presentaion of the project results, credit
2.programming principles of routers in the network with the BGP Protocol
3.network implementation with BGP protocol in the laboratory
4.network configuration of multicast routing protocol
5.network implementation of multicast routing protocols like PIM-DM and SM
6.configuration of IPv6 networks
7.test #1
8.building and testing networks with IPv6
9.Analysis of virtual networks (VPN) in MPLS environment
10.building networks with virtual VPN support in a MPLS environment
11.On TCP throughput
12.examples of measuring throughput of the TCP protocol in different types of networks
13.test#2
14.Presentaion of the project results, credit
Literature
1. Dye M., McDonald R.: Network Fundamentals, CCNA Exploration Companion Guide, Cisco Press, 2007, ISBN: 1-58713-203-6
2. Graziani R., Johnson A.: Routing Protocols and Concepts, CCNA Exploration Companion Guide, Cisco Press, 2007, ISBN: 1-58713-204-4
3. Lewis W.: LAN Switching and Wireless, CCNA Exploration Companion Guide , Cisco Press, 2008, ISBN: 1-58713-202-8
2. Graziani R., Johnson A.: Routing Protocols and Concepts, CCNA Exploration Companion Guide, Cisco Press, 2007, ISBN: 1-58713-204-4
3. Lewis W.: LAN Switching and Wireless, CCNA Exploration Companion Guide , Cisco Press, 2008, ISBN: 1-58713-202-8
Requirements
Requirement for the study of this course is knowledge of the subjects discussed in Data Networks and Fundamentals of networking technologies. This course is based precisely on topic knowledge in the above subjects, which hereafter developed. Both of the above items are not formal, necessary prerequisite to this course. The student will be evaluated as 50 % exam, 30% project and 20% of laboratory exercises.