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CIS 1140 Network FundamentalsChapter 6 – Network Hardware
Collected and CompiledBy JD WillardMCSE, MCSA, Network+, Microsoft IT Academy AdministratorComputer Information Systems InstructorAlbany Technical College
Attention: Accessing Demos• This course presents many demos. • The Demos require that you be logged in to the Virtual
Technical College web site when you click on them to run. • To access and log in to the Virtual Technical College web site:
– To access the site type www.vtc.com in the url window– Log in using the username: CIS 1140 or ATCStudent1– Enter the password: student (case sensitive)
• If you should click on the demo link and you get an Access Denied it is because you have not logged in to vtc.com or you need to log out and log back in.
• If you should click on the demo link and you are taken to the VTC.com web site page you should do a search in the search box for the CompTIA Network+ (2009 Objectives) Course and run the video from within that page.
Objectives• Identify the functions of LAN connectivity
hardware• Install, configure, and differentiate between
network devices such as, NICs, hubs, bridges, switches, routers, and gateways
• Explain the advanced features of a switch and understand popular switching techniques, including VLAN management
• Explain the purposes and properties of routing• Describe common IPv4 and IPv6 routing
protocolsNetwork Devices Overview Demo
Network Hardware Overview Demo
NICs (Network Interface Cards)• Connectivity devices
– Enable device transmission– Transceiver
• Transmits and receives data
• Physical layer and Data Link layer functions– Issue data signals– Assemble and disassemble data frames– Interpret physical addressing information– Determine right to transmit data
• Smart hardware– Prioritization– Network management– Buffering– Traffic-filtering
• Do not analyze information– Added by Layers 3 through 7 OSI model protocols
• Importance– Common to every networking device, network
Network Adapter Overview Demo
Properties of Network Adapter Cards Demo
What Is a NIC Demo
Types of NICs
• Before ordering or installing NIC– Know device interface type
• NIC dependencies– Access method– Network transmission speed– Connector interfaces– Compatible motherboard or device type– Manufacturer– Support for enhanced features
Types of NICs (cont’d.)• Bus
– Circuit, signaling pathway– Motherboard uses to transmit data to computer’s components
• Memory, processor, hard disk, NIC– Differ according to capacity
• Defined by data path width and clock speed– Data path size
• Parallel bits transmitting at any given time• Proportional to attached device’s speed
• Expansion slots– Multiple electrical contacts on motherboard– Allow bus expansion
• Expansion card (expansion board)– Circuit board for additional devices– Inserts into expansion slot, establishes electrical connection– Device connects to computer’s main circuit or bus– Computer centrally controls device
Types of NICs (cont’d.)
• Multiple bus types– PCIe bus: most popular expansion board NIC
• PCIe (Peripheral Component Interconnect Express)– 32-bit bus– Maximum data transfer rate: 1 Gbps– Introduced in 2004
• Determining bus type– Read documentation– Look inside PC case– If more than one expansion slot type:
• Refer to NIC, PC manufacturers’ guidelines• Choose NIC matching most modern bus
PCIe expansion board NIC
Types of NICs (cont’d.)• Peripheral NICs
– Attached externally– Simple installation into
a variety of slots• PCMCIA
• USB
• CompactFlash
• FireWire
– Installing and configuring software may be required
A USB NIC
Types of NICs (cont’d.)• On-Board NICs
– Connect device directly to motherboard
– On-board ports: mouse, keyboard
• New computers, laptops– Use onboard NICs
integrated into motherboard
• Advantages– Saves space
– Frees expansion slots
Motherboard with on-board NICs
Installing and Configuring NICs• Installing NIC hardware
– Read manufacturer’s documentation
• Install expansion card NIC– Gather needed tools– Unplug computer, peripherals, and
network cable– Ground yourself– Open computer case
• Select slot, insert NIC, attach bracket, verify cables
– Replace cover, turn on computer• Configure NIC software
A properly inserted expansion board NIC
Installing and Configuring NICs (cont’d.)• Installing and configuring NIC software
– Device driver• Software enabling device to communicate with operating system
• Purchased computer with a peripheral– Drivers installed
• Add hardware to computer– Must install drivers
• Operating system built-in drivers– Automatically recognize hardware, install drivers
• Drivers not available from operating system– Install and configure NIC software– Available at manufacturer’s Web site
• Verifying NIC functionality– Check whether device can communicate with network
• Diagnostic tools– Use manufacturer’s configuration utility
• Loopback plug needed– Visual inspection of LEDs
• Read manufacturer’s documentation– Use simple commands
• Example: pinging the loopback address
Interpreting LED Indicators
• NICs may have one or more of following lights:– ACT: if blinking, indicates that NIC is
either transmitting or receiving data• If solid, heavy network traffic volume
– LNK: if lit, NIC is functional• In some models, if blinking, NIC
detects network but cannot communicate with it
– TX: if blinking, NIC is functional and transmitting frames
– RX: if blinking, NIC is functional and receiving frames
Troubleshooting Network Adapters Demo
Modular Interfaces• Hot-swappable components
– Can be changed without disrupting operations
• GBIC (Gigabit interface converter)– Standard type of modular interface– Commonly used with Gigabit Ethernet and
fiber channel in the 1990s– May contain RJ-45 or fiber-optic cable ports
• SFPs (small form-factor pluggable)– Provide same form factor as GBIC
• Allow more ports per inch• It interfaces a network device mother
board (for a switch, router, media converter or similar device) to a fiber optic or copper networking cable
• Announced in 2001, it largely made the GBIC obsolete
GBIC (Gigabit interface converter) with an RJ-45 port
SFP (small form-factor pluggable) transceiver for use with fiber connections
Connectivity Devices Overview
Selecting Connectivity Devices Demo
In considering a network expansion solution, it is important to identify the connectivity problems you need to resolve, and then identify the device that is best suited for that situation.
Device Characteristics
Router
Choose a router if you need to:
Filter broadcast traffic to prevent broadcast storms
Reduce the number of devices within a broadcast domain (effectively increasing the number of broadcast domains)
Enforce network security
Switch
Choose a switch if you need to: Provide guaranteed bandwidth between devices
Reduce collisions by decreasing the number of devices in a collision domain (effectively creating multiple collision domains)
Reduce the number of devices within a broadcast domain (creating multiple broadcast domains on a switch is done by using virtual LANs (VLANs))
Implement full-duplex communication
Bridge
Choose a bridge if you need to: Isolate data traffic to one network segment
Link unlike physical media (e.g. twisted pair and coaxial Ethernet) of the same architecture type
Collision Domains vs. Broadcast Domains
• Collision domain – Network or subnetwork where devices share the same transmission medium and where
packets can collide
– Collisions increase as the number of devices in a collision domain increase.
• Broadcast domain – Network or subnetwork where computers can receive frame-level broadcasts from their
neighbors.
– Increasing devices on a network segment increases broadcast traffic on a segment
Device Collision Domain Broadcast Domain
HubAll devices connected to the hub are in the same collision domain.
All devices are in the same broadcast domain.
Bridge or SwitchAll devices connected to a single port are in the same collision domain (each port is its own collision domain).
All devices connected to the bridge or the switch are in the same broadcast domain.
RouterAll devices connected to a single interface are in the same collision domain.
All devices accessible through an interface (network) are in the same broadcast domain. Each interface represents its own broadcast domain if the router is configured to not forward broadcast packets.
Collision Domains Demo
Broadcast Domains Demo
Collision Domains and Broadcast Domains (7:00)
Repeaters and Hubs
• Repeaters– Operate in Physical OSI model layer– One input port, one output port– No means to interpret data– Regenerate signal– Suitable for bus topology networks– Extend network inexpensively
Repeaters/Hubs Demo
Repeaters and Hubs• Hub
– Repeater with more than one output port
– Typically contains multiple data ports
• Patch cables connect printers, servers, and workstations
– Most contain uplink port– Operates at Physical layer– Star or star-based hybrid
topology– Devices share bandwidth,
collision domain, broadcast domain
Hubs Demo
Hubs and repeaters are fairly simple, 'non-intelligent' devices: whatever comes in on one port, gets amplified and send out to ALL other ports, so any network transmission 'fills up/flows into' ALL cable-segments of the network, so only ONE network connection can be active at a time on the complete network!
When multiple system try to communicate at the same time then the signals 'collide'/corrupt each other, making them invalid, time has been wasted and the system will try after a random delay again to transmit, resulting in network slowdown.
Hubs in a network design
Bridges• Devices that connect two network
segments
• Analyze incoming frames– Make decisions on where to direct them
based on frame’s MAC address
• Operate at Data Link OSI model layer
• Single input and single output ports
• Protocol independent
Bridges (cont’d.)
A bridge’s use of a filtering database
• Filtering database (forwarding table)– Contains known MAC addresses
and network locations– Used in decision making
• Filter or forward• New bridge installation
– Learn network– Discover destination packet
addresses– Record in filtering database
• Destination node’s MAC address
• Associated port– All network nodes discovered over
time• Bridge separates one large collision
domain and one broadcast domain into two collision domains and one broadcast domain. The bridge will provide full bandwidth to each port
• Today bridges nearly extinct– Improved router and switch speed,
functionality and lower costs
Bridges/Switches Demo Bridges Demo
Switches• Connectivity devices that subdivide
a network– Segments
• Traditional switches– Operate at Data Link OSI model layer
• Modern switches– Can operate at Layer 3 or Layer 4
• Protocol ignorant• Switches interpret MAC address
information• Common switch components
– Internal processor, operating system, memory, ports
Switches Demo
Switch Installation• Follow manufacturer’s guidelines• General steps (assume Cat 5 or
better UTP)– Verify switch placement– Turn on switch– Verify lights, self power tests– Configure (if necessary)– Connect NIC to a switch port
(repeat for all nodes)– After all nodes connected, turn on
nodes– Connect switch to larger network
(optional)
A switch on a small network
Switching Methods• Difference in switches
– Incoming frames interpretation
– Frame forwarding decisions making
• Four switching modes exist– Two basic methods discussed
• Cut-through mode
• Store-and-forward mode
Switching Methods (cont’d.)
• Cut-through mode– Switch reads frame’s header– Forwarding decision made before receiving entire packet
• Uses frame header: first 14 bytes contains destination MAC address
– Cannot verify data integrity using frame check sequence– Can detect erroneously shortened packets (runts)– Runt detected: wait for integrity check– Cannot detect corrupt packets– Advantage: speed– Disadvantage
• Data buffering (switch flooded with traffic)– Best use
• Small workgroups needing speed• Low number of devices
Switching Methods (cont’d.)• Store-and-forward mode
– Switch reads entire data frame into memory– Checks for accuracy before transmitting information– Transmit data more accurately than cut-through mode– Slower than cut-through mode– Best uses
• Larger LAN environments; mixed environments– Can transfer data between segments running different
transmission speeds
VLANs and Trunking
• VLANs (virtual local area networks)– Logically separate networks
within networks• Groups ports into
broadcast domain
• Broadcast domain– Port combination making a
Layer 2 segment– Ports rely on Layer 2 device
to forward broadcast frames
• Collision domain– Ports in same broadcast
domain• Do not share single
channel
A simple VLAN design
VLANs (4:08)
Configuring VLANs (3:50)
VLANs and Trunking (cont’d.)• Advantage of VLANs
– Flexible• Ports from multiple switches or segments• Use any end node type
– Reasons for using VLAN• Separating user groups• Isolating connections• Identifying priority device groups• Grouping legacy protocol devices• Separating large network into smaller subnets
• Potential problem– Cutting off group from rest of network
• Correct by using router or Layer 3 switch
• Trunking– Switch’s interface carries traffic of multiple VLANs
• Trunk– Single physical connection between switches
• VLAN data separation– Frame contains VLAN identifier in header
VLANs and Trunking (cont’d.)• Switch typically preconfigured
– One default VLAN– Cannot be deleted or
renamed
• Create additional VLANs– Indicate to which VLAN each
port belongs– Additional specifications
• Security parameters, filtering instructions, port performance requirements, network addressing and management options
• Maintain VLAN using switch software
Trunk for multiple VLANs
Understanding VLANs Demo
STP (Spanning Tree Protocol)• IEEE standard 802.1D• Operates in Data Link layer• Prevents traffic loops
– Calculating paths avoiding potential loops
– Artificially blocking links completing loop
• Three steps– Select root bridge based on Bridge
ID– Examine possible paths between
network bridge and root bridge– Disables links not part of shortest
path
Enterprise-wide switched network
Purpose of STP Demo
Election of a Root Bridge Demo
Bridge Protocol Data Units & Port States DemoSpanning Tree Protocol (6:00)
STP (cont’d.)• History
– Introduced in 1980s• Original STP too slow
– RSTP (Rapid Spanning Tree Protocol)
• Newer version• IEEE’s 802.1w standard
• Cisco and Extreme Networks– Proprietary versions
• No enabling or configuration needed– Included in switch operating
software
STP-selected paths on a switched network
Content and Multilayer Switches• Layer 3 switch (routing switch)
– Interprets Layer 3 data
• Layer 4 switch– Interprets Layer 4 data
• Content switch (application switch)– Interprets Layer 4 through Layer 7 data
• Advantages– Advanced filtering– Keeping statistics– Security functions
• Distinguishing between Layer 3 and Layer 4 switch– Manufacturer dependent
• Higher-layer switches– Cost more than Layer 2 switches– Used in network backbone
Managed vs. Unmanaged Switches (2:33)
Multi-Layer Switching Demo
Routers
ROUTERS
Understanding Routing Demo
Routers• Multiport connectivity device
– Directs data between network nodes– Integrates LANs and WANs
• Different transmission speeds, protocols
• Operate at Network layer (Layer 3)– Directs data from one segment or network to another– Logical addressing– Protocol dependent
• Slower than switches and bridges– Need to interpret Layers 3 and higher information
• Traditional stand-alone LAN routers– Being replaced by Layer 3 routing switches
• New niche– Specialized applications
• Linking large Internet nodes• Completing digitized telephone calls
Routers Demo
Router Characteristics and Functions• Intelligence
– Tracks node location– Determine shortest, fastest path between two nodes– Connects dissimilar network types
• Large LANs and WANs– Routers indispensable
• Router components– Internal processor, operating system, memory, input and output jacks,
management control interface
• Multiprotocol routers– Multiple slots– Accommodate multiple network interfaces
• Inexpensive routers– Home, small office use
Router Characteristics and Functions (cont’d.)
• Router capabilities– Connect dissimilar networks
– Interpret Layer 3 addressing
– Determine best data path
– Reroute traffic
• Optional router functions– Filter broadcast transmissions
– Enable custom segregation, security
– Support simultaneous connectivity
– Provide fault tolerance
– Monitor network traffic
– Diagnose problems and trigger alarms
Routers separate collision domains and broadcast domains. Think of each port of the router as a separate collision domain and a separate broadcast domain
Broadcast Domain Devices Demo
Routing Defined Demo
Router Placement• Interior router
– Directs data between nodes on a LAN
• Exterior router– Directs data between nodes
external to a LAN• Border routers
– Connect autonomous LAN with a WAN
• Routing tables– Identify which routers serve
which hosts
Interior Routers
Border Router
Exterior Routers
• Installation– Simple for small office or home office LANs
• Web-based configuration– Challenging for sizable networks
Static vs. Dynamic Routing
Method Description
Static
Static routing requires that entries in the routing table be configured manually.
Network entries remain in the routing table until manually removed.
When changes to the network occur, static entries must be modified, added, or removed.
Dynamic
Routers can dynamically learn about networks by sharing routing information with other routers. The routing protocol defines how routers communicate with each other to share and learn about other networks. The routing protocol determines: The information contained in the routing table
How messages are routed from one network to another
How topology changes (i.e. updates to the routing table) are communicated between routers
Use a routing protocol to allow a router to automatically learn about other networks. The routing protocol generates some network traffic for the process of sharing routes, but has the advantage of being dynamic and automatic (i.e. changes in the network are propagated automatically to other routers).
Static and Dynamic Routing (4:18)
Dynamic Routing Demo
Routing Protocols• Best path
– Most efficient route from one node to another– Dependent on:
• Hops between nodes (number of routers between the source and the destination network)• Current network activity• Unavailable link• Network transmission speed• Topology
– Determined by routing protocol
• Routing metric factors– Number of hops– Throughput on potential path– Delay on a potential path– Load (traffic)– Maximum transmission unit (MTU)– Cost– Reliability of potential path
• Router convergence time– Time router takes to recognize best path
• Change or network outage event– Distinguishing feature
• Overhead; burden on network to support routing protocol
Routing Metrics (3:50)
Link State, Distance Vector, and Hybrid Routing Protocols (5:38)
Next Hop (7:36)
Convergence (3:13)
Routing Tables Demo
Link State or Distance Vector Demo
Routing Protocols (cont’d.)• Distance-vector routing protocols
– Determine best route based on distance to destination– Factors
• Hops, latency, network traffic conditions
• RIP (Routing Information Protocol)– Only factors in number of hops between nodes
• Limits 15 hops– Type of IGP (Interior Gateway Protocol)
• Can only route within internal network– Slower and less secure than other routing protocols
• RIPv2 (Routing Information Protocol Version 2)– Generates less broadcast traffic, more secure– Cannot exceed 15 hops– Less commonly used
• BGP (Border Gateway Protocol)– Communicates using BGP-specific messages– Many factors determine best paths– Configurable to follow policies– Type of EGP (Exterior Gateway Protocol)– Most complex (choice for Internet traffic)
RIP (2:21)
Distance Vector Protocols Demo
Routing Protocols (cont’d.)
• Link-state routing protocol– Routers share information
• Each router independently maps network, determines best path
• OSPF (Open Shortest Path First)– Interior or border router use– No hop limit– Complex algorithm for determining best paths– Each OSPF router
• Maintains database containing other routers’ links
• IS-IS (Intermediate System to Intermediate System)– Codified by ISO– Interior routers only– Supports two Layer 3 protocols
• IP• ISO-specific protocol
– Less common than OSPF
OSPF (2:40)
Link State Protocols Demo
Routing Protocols (cont’d.)
• Hybrid– Link-state and distance-vector characteristics– EIGRP (Enhanced Interior Gateway Routing Protocol)
• Most popular• Cisco network routers only
– EIGRP benefits• Fast convergence time, low network overhead• Easier to configure and less CPU-intensive than OSPF• Supports multiple protocols• Accommodates very large, heterogeneous networks
EIGRP (2:53)
Hybrid Routing Protocols Demo
Routing Protocols (cont’d.)
Summary of common routing protocols
Gateways and Other Multifunction Devices
• Gateway– Combinations of networking hardware and software
• Connecting two dissimilar networks– Connect two systems using different formatting,
communications protocols, architecture– Repackages information– Reside on servers, microcomputers, connectivity
devices, mainframes• Popular gateways
– E-mail gateway, Internet gateway, LAN gateway, Voice/data gateway, Firewall
Summary• Network adapter types vary
– Access method, transmission speed, connector interfaces, number of ports, manufacturer, device type
• Repeaters
– Regenerate digital signal
• Bridges can interpret the data they retransmit
• Switches subdivide a network
– Generally secure
– Create VLANs
• Various routing protocols exist
The End