1 / 22

Network Design and Management

Network Design and Management. CIS 5930-6 CIS 4930-7 Mike Sloderbeck Ray Curci http://www.cs.fsu.edu/courses/netdesign Change to syllabus: quiz/participation now 20% assignments now 40%. Is this the right class for you?. Network class prereq (or permission) Are these terms familiar?

coye
Download Presentation

Network Design and Management

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Network Design and Management • CIS 5930-6 CIS 4930-7 • Mike Sloderbeck • Ray Curci • http://www.cs.fsu.edu/courses/netdesign • Change to syllabus: • quiz/participation now 20% • assignments now 40%

  2. Is this the right class for you? • Network class prereq (or permission) • Are these terms familiar? • TCP, UDP, CSMA/CD, DNS • We won’t cover much of this, but you need to to know these things, so.... • Not heavily research-oriented

  3. What We Will Cover • IP Addresses, Masks and Networks (Class-ful addressing),The Routing Process, Network Matching, Prefix length,Subnet Masks and Hosts per subnet, Subnets other than /24, ARP, Bridges, Switches and VLANS, Typical Physical Networks, especially ones on the lab routers: ethernet, synchronous serial, FDDI, T1 basics, CSU/DSU, Wireless networks

  4. SNMP (in detail) agent, management station, community, SMI, MIB, ASN.1,data object naming, MIB Tree, agent commands, commandline tools (snmpget, snmpwalk, snmpset, snmpnetstat), MRTG views, Cisco SNMP router syntax,Using SNMP tools for network topology discovery • Static Routes,Routing tables,Requirements for Routing Protocols • RIP version 1 (in detail) debug, monitor via ethereal/tcpdump, hop counts, poison reverse, split horizon,

  5. Classless Addresses, Variable Length Subnet Masks (VLSM),Network Design with VLSM, Software tools for performance testing (iperf, traceroute, ping) • RIP version 2 • OSPF (in detail) hello, neighbor, adjacency, link state advertisement (LSA), designated router (DR), backup designated router (BDR), link state database, Dijkstra SPF algorithm, multiple area networks, area 0 • Route Redistribution between protocols, Route Filtering, Route Maps, Internet Service Providers and access, ARIN, Commercial peering,Transit, Private peering

  6. BGP (in detail), EBGP, IBGP, Autonomous System, AS Path, AS Path Prepending, Local Preference, AS Path Filtering, Hot Potato routing, Cisco Access Lists More or less, in one term.

  7. An Idealized Address • “r” bits long (r = p + q) • “p” bits of network id • “q” bits of host id • Example, r=11, p=5, q=6 • How many networks? Hosts per net?

  8. An Idealized Address • Example, r=11, p=5, q=6 • How many networks? • How many hosts per network? • 32 networks, 64 hosts per network • (IP conventions allow fewer)

  9. Novell Address • 8 bytes of network id • 6 bytes of host id (uses MAC) • 64 + 48 bits • fixed p,q

  10. IP v4 as an Ideal Address • r is fixed at 32 bits • p and q are (ideally) variable • If p is 8, 16, or 24, this suggests the Class A, Class B, Class C addresses • For these classes, however, we also restrict the numbering

  11. Class Restrictions • A addresses begin in 0 • B addresses begin in 10 • C addresses begin in 110

  12. Class Restrictions • 0, 10, 110, ?? • But you were probably hoping for the familiar, (in)convenient, and dreaded “dotted decimal” • You’ll be sorry...

  13. Classes Reviewed • 1-126.x.y.z (0 and 127 reserved) • 128-191.X.y.z (X is part of the net id) • 192-223.X.Y.z (X and Y part of net id) • D, E • lots of waste

  14. Subnets • Specify p -- the network mask • p > 8 in the class A space, or • p > 16 in the class B space (FSU), • p > 24 in the class C space • But leave some bits for host ID !!

  15. Supernets • p < 8 in the class A space, or • p < 16 in the class B space • p < 24 in the class C space

  16. Subnets, cont • FSU subnets 128.186.0.0 with a 24 bit mask (255.255.255.0 or /24) • 128.186.17.0 and 128.186.121.0 are different networks (data link layer) • But you don’t have to use a 24 bit mask to subnet a class B

  17. IP Subnetting defined in 1984 • Useful in large, bridged class B nets and to conserve IP addresses • Expressed as dotted decimal or /nn notation • 128.186.121.1 /24 is the same as 128.186.121.1 255.255.255.0 • 192.168.1.1 /28 is the same as 192.168.1.1 255.255.255.240

  18. Network Matching • Use the network mask • Bit-wise compare the two networks, using the mask length • 192.168.1.2 /28 and 192.168.1.250 /28 are on different networks (or different subnets, if you prefer that terminology). • 192.168.1.2 /28 and 192.168.1.3 /28 are on the same subnet. (use the data link)

  19. Network Masks • Note that network masks work for classful network matching also. • 128.186.234.2 /16 and 128.187.123.4 /16 must be on different networks when the first 16 bits of the addresses are compared. • Modern IP routing tables include a mask for every network route.

  20. Host Addresses per Network • The lowest address refers to the network itself and can’t be used for a host. Eg. 192.168.1.0 /24 • The highest address is reserved for the IP broadcast address. Eg. 192.168.1.255 /24 • So in this network there are 254 available IP addresses for hosts and routers.

  21. Host Addresses in a Subnet • The address 192.168.1.16 /28 refers to the network and can’t be used for a host. • The address 192.168.1.31 /28 is reserved for the IP broadcast address. • This network has 14 IP addresses available for hosts and routers.

  22. Examples • Subnet 172.17.0.0 so that each subnet has at least 700 host addresses • Subnet 192.168.100.0 so that each subnet has two usable host addresses • How many subnets of the original network are obtained in each case? • Review Doyle, Fig 2.16, 2.17, 2.18

More Related