1. Cisco – Semester 3 – Chapter 1 Review of OSI Model and Routers

2. OSI 1-4 The type and speed of LAN and WAN media to be implemented How data are sent across the media The type of addressing schemes used How data will be reliably sent across the network and how flow control will be accomplished The type of routing protocol implemented

3. Why Use ? Divide the aspects of network operation into less complex elements. Define standard interfaces for plug-and-play compatibility. Enable engineers to specialize design and development efforts on modular functions. Promote symmetry in the different network modular functions so that they work together. Prevent changes in one area from affecting other areas, so each area can evolve more quickly. Divide the complexity of networking into separate, easy to learn operations.

4. Vocabulary To Know Interfaces (as used in the general software sense as the boundary between conceptual and functional layers), Modular engineering (treating everything outside the problem at hand as “black boxes” with assumed input and output properties) Interoperable technology (assuring that hardware and software from different internal design and external vendor sources all works together). SAP (Service Access Provider)

5. Review of OSI Model Do Lab Activity 1.1.2 Datagram Units –Data, Segments, Packets, Frames, Bits Encapsulation –Segments are placed in packets with packet header at layer 3 –Packets are placed in frames with frame header and trailer at layer 4 –The frame is encoded into 1s and 0s to traverse the network (can use both LANS and WANS)

6. Ethernet Families Designed to fill gap between high-speed computer room applications and slow WAN connections Ethernet and IEEE 802.3--LAN specifications, which operate at 10 Mbps over coaxial and twisted-pair cable. 100-Mbps Ethernet--A single LAN specification, also known as Fast Ethernet, which operates at 100 Mbps over twisted-pair cable. 1000-Mbps Ethernet--A single LAN specification, also known as Gigabit Ethernet, which operates at 1000 Mbps (1 Gbps) over fiber and twisted-pair cables.

7. Ethernet Families- refer to 3.2.2 10BASE2--Known as thin Ethernet, 10BASE2 allows network segments up to 185 meters on coaxial cable. 10BASE5--Known as thick Ethernet, 10BASE5 allows network segments up to 500 meters on coaxial cable. 10BASE-T--10BASE-T carries Ethernet frames on inexpensive twisted-pair wiring. (becoming legacy Ethernet)

8. MAC Addresses 48 bits or 12 Hex digits –A1 BB C3 DD ED 11 or 1345.e32a.123d Used for hosts, printers, Router Interfaces

9. Layer 3 Protocols IP, ICMP, RARP, and ARP IP provides connectionless, best-effort delivery Routing of datagrams. It is not concerned with the content of the datagrams (packets); instead, it looks for a way to move the datagrams (packets) to their destinations. Internet Control Message Protocol (ICMP) provides control and messaging capabilities. Address Resolution Protocol (ARP) determines the data link layer addresses for known IP addresses. Reverse ARP (RARP) determines network addresses when data link layer addresses are known.

10. Subnetting End stations communicate with servers, hosts, or other end stations. Each node using the TCP/IP protocol suite has a unique 32-bit logical address, known as the IP address. Within a TCP/IP environment, each network is seen as a single unique address. That address must be reached before an individual host within that network can be contacted.

11. Routers Determine best path Switch packet out correct interface port Provides best delivery service IP Addresses include network (network & subnetwork) and host address Router ands subnet mask to IP address to determine correct subnet (interface) to route packet

12. ICMP Messages Destination unreachable Time exceeded Parameter problem Source quench Redirect Echo Echo reply Timestamp Timestamp reply Address request Information request Address reply Information reply

13. Ping Can use DOS command prompt to ping an IP address Router discards packet if unreachable message is returned

14. ARP If the destination MAC address is not known, the source must send out an ARP request to determine what it is Local ARP is used when both the requesting host and the destination host share the same medium, or wire Router Proxy (router supplies its MAC address) is used when destination host is on another subnet

15. Ethernet to Token Ring Lower layer framing must change as the router switches packet traffic from Ethernet on Network 1 to Token Ring on Network 2 The Layer 3 addressing for source and destination remains the same. The destination address remains Network 2, Host 5, despite the different lower layer encapsulations.

16. IP Routing Tables Consist of IP addresses and next hop pairs The process examines the header to determine the destination network and then references the routing table that associates networks to outgoing interfaces. The original frame is stripped off and discarded. The packet is again encapsulated in the data link frame for the selected interface and stored in a queue for delivery to the next hop in the path.

17. Dynamic and Static Routing Static Routing –Allows network administrator to specify what is to be advertised about restricted partitions. – For security reasons, the administrator can hide parts of a network –Sufficient for stub networks Dynamic Routing –Reveals everything known about a network

18. Routed and Routing Protocols Routed Protocol –Any network protocol that provides enough information in its network layer address to allow a packet to be forwarded from host to host based on the addressing scheme. IP, IPX, Appletalk, Decnet Routing Protocol –supports a routed protocol by providing mechanisms for sharing routing information. Moves messages between routers RIP, IGRP, EIGRP, OSPF

19. Dynamic Routing Success Maintenance of a routing table Timely distribution of knowledge in the form of routing updates to other routers Routing Protocol Describes –How updates are sent –What knowledge is contained in these updates –When to send this knowledge –How to locate recipients of the updates Interior Gateway protocols are used in autonomous networks; Exterior are used between autonomous systems

20. Convergence the time it takes all the routers in a network to share a consistent view of the network All routers in a network are operating with the same knowledge Routers must re-compute tables (disrupts routing) Time varies among different protocols

21. Distance Vector Compute a metric – forwarded to next router –Hop count –Bandwidth –Delay –Load –Administrative Distance Cannot know exact nature of topology

22. Link State Maintains full knowledge of distant routers and how they interconnect. uses link-state advertisements (LSAs), a topological database, the SPF protocol, the resulting SPF tree, a routing table of paths and ports to each network

23. Comparison Distance Vector –Views topology from neighbor’s perspective –Adds vectors from neighbor –Frequent updates –Slow to converge –Passes copies of routing tables Link State –Common view of entire network topology –Calculates shortest path –Event triggered updates –Faster Convergence –Link-state updates passed to other neighbors

24. Router Commands Router Rip –Hop count is used as the metric for path selection. –The maximum allowable hop count is 15. –Routing updates are broadcast every 30 seconds by default. Router (config-if)# –Router Rip –Network 1.0.0.0 –Network 1.2.2.1

25. Reliable Transport – Layer 4 Segment upper-layer applications Establish a connection Transfer data Provide reliability with windowing Use acknowledgment techniques Different applications can send data segments on a first-come, first-served basis. –Such segments can be intended for the same destination or for many different destinations.