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ITEC 275 Computer Networks – Switching, Routing, and WANs

ITEC 275 Computer Networks – Switching, Routing, and WANs. Accuracy is a measurement of lost packets. This measurement is achieved by keeping track of lost packets while measuring response time. . Week 3 Robert D’Andrea. Some slides provide by Priscilla Oppenheimer and used with permission.

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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 Accuracy is a measurement of lost packets. This measurement is achieved by keeping track of lost packets while measuring response time. Week 3 Robert D’Andrea Some slides provide by Priscilla Oppenheimer and used with permission

  2. Agenda • Review • Learning Activities • Analyzing an Existing Network • Analyzing Traffic in an Existing Network • QoS • Introduce homework problems

  3. What’s the Starting Point? • According to Abraham Lincoln: • “If we could first know where we are and whither we are tending, we could better judge what to do and how to do it.”

  4. Where Are We? When we characterize the infrastructure of a network, we develop a set of network maps and locate major devices and network segments. Developing a network map should involve understanding traffic flow, performance characteristics of network segments, and insight into where the users are concentrated and the level of traffic a network design must support.

  5. Where Are We? • Characterize the existing internetwork in terms of: • Its infrastructure • Logical structure (modularity, hierarchy, topology) • Physical structure • Addressing and naming • Wiring and media • Architectural and environmental constraints • Health

  6. How to Start? • Characterization can start by using a top-down approach. • Starting with a map or set of maps depicting a high-level abstraction of informatiom • Geographical information • WAN • WAN to LAN • Buildings and floors • Rooms containing servers, routers, mainframes, and switches • Virtual information

  7. How to Start? • Characterizing large complex networks should reflect influence from the OSI reference model. • A network map should depict applications and services used by the network users. Internal and external web sites Email and external data access entries Ftp operations Printer and file sharing devices DHCP, DNS, SNMP Router interface names, firewalls, NAT, IDS, and IPS

  8. Get a Network Map Medford Fast Ethernet 50 users Roseburg Fast Ethernet 30 users Frame Relay CIR = 56 Kbps DLCI = 5 Frame Relay CIR = 56 Kbps DLCI = 4 Gigabit Ethernet Grants Pass HQ Gigabit Ethernet Grants Pass HQ Fast Ethernet 75 users FEP (Front End Processor) IBMMainframe T1 Web/FTP server Eugene Ethernet 20 users T1 Internet

  9. Characterize Addressing and Naming • IP addressing for major devices, client networks, server networks, private needing translation, and so on • Any addressing oddities, such as discontinuous subnets? • Any strategies for addressing and naming? • Route summarization reduces routes in a router • For example, sites may be named using airport codes • San Francisco = SFO, Oakland = OAK

  10. Discontiguous Subnets Area 0 Network 192.168.49.0 Router A Router B Area 1 Subnets 10.108.16.0 - 10.108.31.0 Area 2 Subnets 10.108.32.0 - 10.108.47.0

  11. Characterize the Wiring and Media • Single-mode fiber • Multi-mode fiber • Shielded twisted pair (STP) copper • Unshielded-twisted-pair (UTP) copper • Coaxial cable • Microwave • Laser • Radio • Infra-red

  12. Horizontal Wiring Work-Area Wiring Wallplate Telecommunications Wiring Closet Vertical Wiring (Building Backbone) Main Cross-Connect Room (or Main Distribution Frame) Intermediate Cross-Connect Room (or Intermediate Distribution Frame) Campus Backbone Building A - Headquarters Building B Campus Network Wiring

  13. Architectural Constraints • Make sure the following are sufficient • Air conditioning • Heating • Ventilation • Power • Protection from electromagnetic interference • Doors that can lock

  14. Architectural Constraints • Make sure there’s space for: • Cabling conduits • Patch panels • Equipment racks • Work areas for technicians installing and troubleshooting equipment

  15. Wireless Installation • Inspect the architecture and environment constraints of the site to determining the feasibility of a wireless transmission. • Wireless transmission is RF (radio frequency) • A wireless expert should be hired • Network designers can install access points will be located and where the people concentration will be located • Access point is based on signal loss between the access point and the user of the access point.

  16. RF Phenomena Wireless Installations • Reflection causes the signal to bounce back on itself. • Absorption occurs as the signal passes through materials • Refraction is when a signal passes through one medium of one density and then through another medium of another density. Signal will bend. • Diffraction when a signal can pass in part through a medium more easily in one part than another

  17. RF Phenomena Wireless Installations • A wireless Site Survey should be performed on the existing network for signal propagation, strength, and accuracy in different areas. • NIC cards ship with utilities on them to measure signal strength • Signal strength can be determined using a protocol analyzer • Access points send beacon frames every 100 milliseconds (ms). Use a protocol analyzer to analyze the signal strength being emitted from the different grid locations of the access points.

  18. RF Phenomena Wireless Installations - Use a protocol analyzer to capture CRC errors. These errors stem from corruption and collisions. - Observe if frames are being lost in transmission - Observe the acknowledgment (ACK) and fame retries after a missing ACK. ACK is called a control frame. Clients and access points use to implement a retransmission mechanism

  19. RF Phenomena Wireless Installations • Wired Ethernet Detects collisions through CSMA/CD (802.11) Ethernet uses CSMA/CA as the access method to gain access of the wire. An ACK control frame is returned to a sender for packet received. If a frame does not receive an ACK, it is retransmitted.

  20. Check the Health of the Existing Internetwork • Baseline network performance with sufficient time and at a typical time • Baseline availability gather information from the customer on MTBF and MTTR • Baseline bandwidth utilization during a specific time frame. This is usually a percentage of capacity. • Accuracy is an upper layer protocol’s responsibility. A frame with a bad CRC is dropped and retransmitted. A good threshold rule for handling errors is that there should be no more than one bad frame per megabyte of data.

  21. Check the Health of the Existing Internetwork -Accuracy is a measurement of lost packets. This measurement is achieved by keeping track of lost packets while measuring response time. -Switches have replaced hubs. - There should be fewer than 0.1 percent of frames encounter collisions. - There should be no late collisions. Indicate bad cabling, cabling longer than 100 meters, bad NIC, or duplex mismatch.

  22. Check the Health of the Existing Internetwork - Autonegotiation has received it’s share of critism in the past for being inaccurate when setting up a point-to-point link half duplex and the other being set to full duplex. - autonegotiation of speed is usually not a problem. Set up incorrectly, it does not work. The speeds are 10 Mbps, 100 Mbps, or 1000 Mbps.

  23. Check the Health of the Existing Internetwork - Category 3 cable will support 10MBps, but not 100 MBps and higher. Errors increase. • Efficiency is linked to large frame sizes. Bandwidth utilization is optimized for efficiency when applications and protocols are in large sized frames. • Change window sizes on clients and servers. Increasing maximum transmission unit (MTU). • Able to ping and telnet but not be able to use HTTP, and FTP. • A hump exist on the sides of the average transmission. • Runt frames (less than 64 bytes) are a result of collisions on the same shared Ethernet segment.

  24. Check the Health of the Existing Internetwork • Response time can be measured using the round-trip time (RTT)ping command. Observe response time on a user workstation. Run typical applications to get a response. Response time for network services protocols, such as, DHCP and DNS. • Status of major routers, switches, and firewalls

  25. Characterize Availability Cause of Last Major Downtime Fix for Last Major Downtime Date and Duration of Last Major Downtime MTBF MTTR • Enterprise • Segment 1 • Segment 2 • Segment n

  26. Network Utilization in Minute Intervals

  27. Network Utilization in Hour Intervals

  28. Bandwidth Utilization by Protocol Relative Network Utilization Absolute Network Utilization Multicast Rate Broadcast Rate • Protocol 1 • Protocol 2 • Protocol 3 • Protocol n

  29. Characterize Packet Sizes

  30. Characterize Response Time Node A Node B Node C Node D • Node A • Node B • Node C • Node D X X X X

  31. Check the Status of Major Routers, Switches, and Firewalls • show buffers • show environment • show interfaces • show memory • show processes • show running-config • show version

  32. Tools • Protocol analyzers • Multi Router Traffic Grapher (MRTG) • Remote monitoring (RMON) probes • Cisco Discovery Protocol (CDP) • Cisco IOS NetFlow technology • CiscoWorks

  33. Network Traffic Factors • Traffic flow • Location of traffic sources and data stores • Traffic load • Traffic behavior • Quality of Service (QoS) requirements

  34. User Communities User Community Name Size of Community (Number of Users) Location(s) of Community Application(s) Used by Community

  35. Data Stores Data Store Location Application(s) Used by User Community(or Communities)

  36. Traffic Flow • Destination 1 Destination 2 Destination 3 Destination MB/sec MB/sec MB/sec MB/sec • Source 1 • Source 2 • Source 3 • Source n

  37. Library and Computing Center Traffic Flow Example 10-Mbps Metro Ethernet to Internet 30 Library Patrons (PCs) 30 Macs and 60 PCs in Computing Center App 1 108 Kbps App 2 60 Kbps App 3 192 Kbps App 4 48 Kbps App 7 400 Kbps Total 808 Kbps Server Farm App 2 20 Kbps App 3 96 Kbps App 4 24 Kbps App 9 80 Kbps Total 220 Kbps 25 Macs 50 PCs 50 PCs Arts and Humanities Administration App 1 30 Kbps App 2 20 Kbps App 3 60 Kbps App 4 16 Kbps Total 126 Kbps App 1 48 Kbps App 2 32 Kbps App 3 96 Kbps App 4 24 Kbps App 5 300 Kbps App 6 200 Kbps App 8 1200 Kbps Total 1900 Kbps Math and Sciences 30 PCs 50 PCs Business and Social Sciences

  38. Types of Traffic Flow • Terminal/host • Client/server • Thin client • Peer-to-peer • Server/server • Distributed computing

  39. Traffic Flow for Voice over IP • The flow associated with transmitting the audio voice is separate from the flows associated with call setup and teardown. • The flow for transmitting the digital voice is essentially peer-to-peer. • Call setup and teardown is a client/server flow • A phone needs to talk to a server or phone switch that understands phone numbers, IP addresses, capabilities negotiation, and so on.

  40. Network ApplicationsTraffic Characteristics Name of Application Type of Traffic Flow Protocol(s) Used by Application User Communities That Use the Application Data Stores (Servers, Hosts, and so on) Approximate Bandwidth Requirements QoS Requirements

  41. Traffic Load • To calculate whether capacity is sufficient, you should know: • The number of stations • The average time that a station is idle between sending frames • The time required to transmit a message once medium access is gained • That level of detailed information can be hard to gather, however

  42. Size of Objects on Networks • Terminal screen: 4 Kbytes • Simple e-mail: 10 Kbytes • Simple web page: 50 Kbytes • High-quality image: 50,000 Kbytes • Database backup: 1,000,000 Kbytes or more

  43. Traffic Behavior • Broadcasts • All ones data-link layer destination address • FF: FF: FF: FF: FF: FF • Doesn’t necessarily use huge amounts of bandwidth • But does disturb every CPU in the broadcast domain • Multicasts • First bit sent is a one • 01:00:0C:CC:CC:CC (Cisco Discovery Protocol) • Should just disturb NICs that have registered to receive it • Requires multicast routing protocol on internetworks

  44. Network Efficiency • Frame size • Protocol interaction • Windowing and flow control • Error-recovery mechanisms

  45. QoS Requirements • ATM service specifications • Constant bit rate (CBR) • Realtime variable bit rate (rt-VBR) • Non-realtime variable bit rate (nrt-VBR) • Unspecified bit rate (UBR) • Available bit rate (ABR) • Guaranteed frame rate (GFR)

  46. QoS Requirements per IETF • IETF integrated services working group specifications • Controlled load service • Provides client data flow with a QoS closely approximating the QoS that same flow would receive on an unloaded network • Guaranteed service • Provides firm (mathematically provable) bounds on end-to-end packet-queuing delays

  47. QoS Requirements per IETF • IETF differentiated services working group specifications • RFC 2475 • IP packets can be marked with a differentiated services codepoint (DSCP) to influence queuing and packet-dropping decisions for IP datagrams on an output interface of a router

  48. Summary • Characterize the existing internetwork before designing enhancements • Helps you verify that a customer’s design goals are realistic • Helps you locate where new equipment will go • Helps you cover yourself if the new network has problems due to unresolved problems in the old network

  49. Summary • Continue to use a systematic, top-down approach • Don’t select products until you understand network traffic in terms of: • Flow • Load • Behavior • QoS requirements

  50. Review Questions • What factors will help you decide if the existing internetwork is in good enough shape to support new enhancements? • When considering protocol behavior, what is the difference between relative network utilization and absolute network utilization? • Why should you characterize the logical structure of an internetwork and not just the physical structure? • What architectural and environmental factors should you consider for a new wireless installation?

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