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ITEC 275 Computer Networks – Switching, Routing, and WANs

ITEC 275 Computer Networks – Switching, Routing, and WANs. Week 7 Robert D’Andrea. Some slides provide by Priscilla Oppenheimer and used with permission. Agenda. Learning Activities Domain Name Server (DNS) Summarization Root Owner DNS Routing tables Spanning Tree Protocol

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ITEC 275 Computer Networks – Switching, Routing, and WANs

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  1. ITEC 275 Computer Networks – Switching, Routing, and WANs Week 7 Robert D’Andrea Some slides provide by Priscilla Oppenheimer and used with permission

  2. Agenda • Learning Activities • Domain Name Server (DNS) • Summarization • Root Owner DNS • Routing tables • Spanning Tree Protocol • Rapid Spanning Tree Protocol • Static versus Dynamic Routing • Routing Protocols and Characteristics

  3. DNS Domain Names

  4. Interpreting a DNS domain names DNS has a method of noting and interpreting the fully qualified path to a DNS domain name similar to the way full paths to files or directories are noted or displayed at a command prompt. For example, a directory tree path helps point to the exact location of a file stored on your computer. For Windows computers, the back slash (\) indicates each new directory that leads to the exact location of a file. For DNS, the equivalent is a period (.) indicating each new domain level used in a name.

  5. Interpreting File Names UNIX uses the concept of relative and absolute file names. If a file name is preceded by a forward slash (e.g. /bin), the name is absolute. If the name is without a leading slash, it is considered relative to your current working directory.

  6. Interpreting a DNS domain names For DNS, an example of a domain name with multiple levels is the following, a fully qualified domain name (FQDN): host-a.example.microsoft.com. Unlike the file name example, a DNS FQDN, when read from left to right, moves from its most specific information (the DNS name for a computer called "host-a") to its highest or most general piece of information (the trailing period (.) that indicates the root of the DNS name tree). This example shows the four separate DNS domain levels that lead away from the specific host location of "host-a":

  7. Interpreting a DNS domain names 1. The "example" domain, which corresponds to a subdomain where the computer name "host-a" is registered for use. 2. The "microsoft" domain, which corresponds to the parent domain that roots the "example" subdomain. 3. The "com" domain, which corresponds to the top-level domain designated for use by business or commercial organizations that roots the "microsoft" domain. 4. The trailing period (.), which is a standard separator character used to qualify the full DNS domain name to the root level of the DNS namespace tree.

  8. Root Servers When a computer on the Internet needs to resolve a domain name, it uses resolver software to do the lookup. A resolver breaks the name up into its labels from right to left. The first component is queried using a root server to obtain the responsible authoritative server. Queries for each name are performed until a name server returns the answer of the original query.

  9. Interpreting a DNS domain names As of 2013, there are 13 root name servers, with names in the form letter.root-server.net. This does not mean that there are only 13 physical servers; each site uses redundant computer equipment to provide reliable service in when hardware and software fail on occasion. View: www.root-servers.org

  10. Route Summarization

  11. Classful Boundary Summarization

  12. Routing Tables

  13. Dual Stack and Tunneling IPv4/IPv6

  14. Stateless Autoconfiguration

  15. Switching and Routing Choices • Switching • Layer 2 transparent bridging (switching) • Multilayer switching • Spanning Tree Protocol enhancements • VLAN technologies • Routing • Static or dynamic • Distance-vector and link-state protocols • Interior and exterior • Etc.

  16. Selection Criteria for Switching and Routing Protocols • Network traffic characteristics • Bandwidth, memory, and CPU usage • The number of peers supported • The capability to adapt to changes quickly • Support for authentication

  17. Making Decisions • Goals must be established • Many options should be explored • The consequences of the decision should be investigated • Contingency plans should be made • A decision table can be used. Decision tables are composed of rows and columns. Each row corresponds to a single rule, with the columns defining the conditions and actions of the rules.

  18. Example Decision Table

  19. Transparent Bridging (Switching) Tasks • Ethernet switches and bridges use transparent bridging. • A transparent bridge connects one or more LAN segments so that end systems on different segments can communicate with each other transparently. An end system sends a frame to a destination without knowing whether the destination is local or on the other side of the bridge.

  20. Transparent Bridging (Switching) Tasks • Forward frames transparently • Learn which port to use for each MAC address • Flood frames when the destination unicast address hasn’t been learned yet • Filter frames from going out ports that don’t include the destination address • Flood broadcasts and multicasts

  21. Definitions • STP is a bridge protocol that uses the STA (Spanning Tree Algorithm) to find redundant links dynamically and create a spanning-tree topology database. Bridges exchange BPDU (Bridge Protocol Data Unit) messages with other bridges to detect loops. • BPDU STP hello packet that is sent out at configurable intervals to exchange information among bridges in the network.

  22. Transparent Bridging

  23. Switching Table on a Bridge or Switch MAC Address Port 08-00-07-06-41-B9 1 2 00-00-0C-60-7C-01 3 00-80-24-07-8C-02

  24. Cisco Spanning Tree Protocol Enhancements • PortFastis a Cisco feature. It supports the concept of a switch edge port. • UplinkFast and Backbone Fast. UpLinkFast is a Cisco feature that is configured on access layer switches. Improves the convergence time of STP. • Unidirectional link detection is a hardware failure detection between switches. • Loop Guard is a Cisco product. Supports the prevention of loops caused by blocking port erroneously moving to the forwarding state.

  25. Redundant Uplinks Core Layer X • If a link fails, how long will STP take to recover? • Use UplinkFast to speed convergence Distribution Layer Switch B Switch C X Primary Uplink Secondary Uplink Access Layer X = blocked by STP Switch A

  26. Protocols for Transporting VLAN Information • Inter-Switch Link (ISL) • Tagging protocol • Cisco proprietary • IEEE 802.1Q • Tagging protocol • IEEE standard • VLAN Trunk Protocol (VTP) • VLAN management protocol is a switch-to-switch and switch-to-router configuration.

  27. Protocols for Transporting VLAN Information • VLAN Trunk Protocol (VTP) • The VLAN management protocol exchanges VLAN configuration changes as they are made to the network. VTP manages additions, deletions, and renaming of VLANs on a campus network without requiring manual intervention at each switch.

  28. Selecting Routing Protocols • They all have the same general goal: • To share network reachability information among routers • They differ in many ways: • Interior versus exterior • Metrics supported hop count or bandwidth. • Dynamic versus static and default • Distance-vector versus link-sate • Classful versus classless • Scalability

  29. Interior Versus Exterior Routing Protocols • Interior routing protocols are used within an autonomous system • Exterior routing protocols are used between autonomous systems Autonomous system (two definitions that are often used): “A set of routers that presents a common routing policy to the internetwork” “A network or set of networks that are under the administrative control of a single entity”

  30. Routing Protocol Metrics • Metric: the determining factor used by a routing algorithm to decide which route to a network is better than another • Examples of metrics: • Bandwidth - capacity • Delay - time • Load - amount of network traffic • Reliability - error rate • Hop count - number of routers that a packet must travel through before reaching the destination network • Cost - arbitrary value defined by the protocol or administrator

  31. Routing Algorithms • Static routing • Calculated beforehand, offline • Default routing • “If I don’t recognize the destination, just send the packet to Router X” • Cisco’s On-Demand Routing • Routing for stub networks • Uses Cisco Discovery Protocol (CDP) • Dynamic routing protocol • Distance-vector algorithms • Link-state algorithms

  32. Routing Algorithms Stub network has only one default path to non-local hosts and no outside network knowledge. Non-local stub network traffic uses a single logical path when traveling in and out of the network. A good example would be an individual or group that uses only one router to link to an internet service provider (ISP). The individual or group are considered stub networks by the ISP.

  33. Routing Algorithms The default route is the IP address of the next hop when no other routes are known. To configure the default route to be 192.168.1.1: config t ip route 0.0.0.0 0.0.0.0 192.168.1.1 An interface can be used as an alternative to and IP address. To use serial0/0 for destinations not in the routing table, use: ip route 0.0.0.0 0.0.0.0 serial 0/0

  34. Routing Algorithms A default route of a computer that is participating in computer networking is the packet forwarding rule (route) taking effect when no other route can be determined for a given Internet Protocol (IP) destination address. All packets for destinations not established in the routing table are sent via the default route. This route generally points to another router, which treats the packet the same way: If a route matches, the packet is forwarded accordingly, otherwise the packet is forwarded to the default route of that router. The process repeats until a packet is delivered to the destination. Each router traversal counts as one hop in the distance calculation for the transmission path.

  35. Routing Algorithms Cisco’s On- Demand Routing The Cisco Discovery Protocol (CDP) is a Cisco proprietary protocol that, amongst other things, is used to discover other Cisco devices on either broadcast or non-broadcast media. CDP provides administrators with information that includes the IP address, software version, as well as the capabilities of the neighbor device. On-Demand Routing is an enhancement to Cisco Discovery Protocol that advertises the connected IP prefix or prefixes of a stub router via CDP. ODR also supports VLSM, which means that it can be used in just about any network.

  36. Routing Algorithms Cisco’s On- Demand Routing It is important to know that ODR is not a routing protocol. Instead, it is simply an enhancement to CDP that is used to dynamically propagate routing information at Layer 2. The primary reasons ODR is often incorrectly referred to as a routing protocol is because it allows routers to dynamically exchange routing information. The second reason is because ODR is enabled using the router odrglobal configuration command.

  37. Routing Algorithms Cisco’s On- Demand Routing The primary benefits of using ODR is that it is not CPU intensive and it consumes very little bandwidth. 

  38. Routing Algorithms Cisco’s On- Demand Routing

  39. Static Routing Example 172.16.20.1 172.16.20.2 172.16.40.1 172.16.40.2 Router A Router B Router C s0 s0 s0 s1 e0 e0 e0 172.16.10.1 172.16.30.1 172.16.50.1 Host A Host B Host C 172.16.10.2 172.16.30.2 172.16.50.2 RouterA(config)#ip route 172.16.50.0 255.255.255.0 172.16.20.2 Send packets for subnet 50 to 172.16.20.2 (Router B)

  40. Default Routing Example 172.16.20.1 172.16.20.2 172.16.40.1 172.16.40.2 Router A Router B Router C s0 s0 s0 s1 e0 e0 e0 172.16.30.1 172.16.50.1 172.16.10.1 Host A Host B Host C 172.16.10.2 172.16.30.2 172.16.50.2 RouterA(config)#ip route 0.0.0.0 0.0.0.0 172.16.20.2 If it’s not local, send it to 172.16.20.2 (Router B)

  41. Distance-Vector Routing • Router maintains a routing table that lists known networks, direction (vector) to each network, and the distance to each network • Router periodically (every 30 seconds, for example) transmits the routing table via a broadcast packet that reaches all other routers on the local segments • Router updates the routing table, if necessary, based on received broadcasts

  42. Distance-Vector Routing Tables Router A Router B 172.16.0.0 192.168.2.0 Router A’s Routing Table Router B’s Routing Table Network Distance Send To 172.16.0.0 0 Port 1 192.168.2.0 1 Router B Network Distance Send To 192.168.2.0 0 Port 1 172.16.0.0 1 Router A

  43. Link-State Routing • Routers send updates only when there’s a change • Router that detects change creates a link-state advertisement (LSA) and sends it to neighbors • Neighbors propagate the change to their neighbors • Routers update their topological database if necessary

  44. Distance-Vector Vs. Link-State • Distance-vector algorithms keep a list of networks, with next hop and distance (metric) information • Link-state algorithms keep a database of routers and links between them • Link-state algorithms think of the internetwork as a graph instead of a list • When changes occur, link-state algorithms apply Dijkstra’s shortest-path algorithm to find the shortest path between any two nodes

  45. Link-State Routing Protocol

  46. Choosing Between Distance-Vector and Link-State Choose Distance-Vector • Simple, flat topology • Hub-and-spoke topology • Junior network administrators • Convergence time not a big concern Choose Link-State • Hierarchical topology • More senior network administrators • Fast convergence is critical

  47. Dynamic IP Routing Protocols Distance-Vector • Routing Information Protocol (RIP) Version 1 and 2 • Interior Gateway Routing Protocol (IGRP) • Enhanced IGRP • Border Gateway Protocol (BGP) Link-State • Open Shortest Path First (OSPF) • Intermediate System-to-Intermediate System (IS-IS)

  48. Routing Information Protocol (RIP) • First standard routing protocol developed for TCP/IP environments • RIP Version 1 is documented in RFC 1058 (1988) • RIP Version 2 is documented in RFC 2453 (1998) • Easy to configure and troubleshoot • Broadcasts its routing table every 30 seconds; 25 routes per packet • Uses a single routing metric (hop count) to measure the distance to a destination network; max hop count is 15

  49. RIP V2 Features • Includes the subnet mask with route updates • Supports prefix routing (classless routing, supernetting) • Supports variable-length subnet masking (VLSM) • Includes simple authentication to foil crackers sending routing updates

  50. IGRP Solved Problems with RIP • 15-hop limitation in RIP • IGRP supports 255 hops • Reliance on just one metric (hop count) • IGRP uses bandwidth, delay, reliability, load • (By default just uses bandwidth and delay) • RIP's 30-second update timer • IGRP uses 90 seconds

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