Network Design Essentials
Jan 11, 2016
Network Design Essentials
Guide to Networking Essentials, Fifth Edition 2
Contents
1. Examining the Basics of a Network Layout
2. Understanding Standard Topologies
3. Examining Variations of Physical Topologies
4. Hubs and Switches
5. Constructing a Network Layout
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1. Examining the Basics of a Network Layout
• To implement a network, you must first decide how to best situate the components in a topology– Topology refers to the physical layout of its
computers, cables, and other resources, and also to how those components communicate with each other
• The arrangement of cabling is the physical topology
• The path that data travels between computers on a network is the logical topology
– Topology has a significant effect on the network’s performance and growth, and equipment decisions
2. Understanding Standard Topologies
2.1. Physical Bus Topology
2.2. Logical Bus Topology
2.3. Physical Ring Topology
2.4. Logical Ring Topology
2.5. Physical Star Topology
2.6. Wireless Topologies
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• Networks are based on three physical topologies– A bus consists of a series of computers connected
along a single cable segment– Computers connected via a central concentration
point (hub) are arranged in a star topology– Computers connected to form a loop create a ring
• Physical topologies describe cable arrangement– How the data travels along those cables might
represent a different logical topology• The logical topologies that dominate LANs
include bus, ring, and switching, all of which are usually implemented as a physical star
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2.1. Physical Bus Topology
Low fault tolerance
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2.1.1. Signal Propagation
• Computers communicate by sending information across the media as a series of signals– In a typical (copper wire) physical bus, those signals
are sent as electrical pulses that travel along the length of the cable in all directions
– The signals continue to travel until they weaken enough so as not to be detectable or until they encounter a device that absorbs them
– This traveling across the medium is called signal propagation
• At the end of a cable, the signal bounces back
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2.1.2. Signal Bounce
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2.1.3. Cable Termination
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2.1.4. Cable Failure
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2.2. Logical Bus Topology
• Logical topologies describe the path that data travels from computer to computer
• A physical bus topology is almost always implemented as a logical bus as well– Technology has moved past the physical bus, but a
logical bus topology is still in use on some physical topologies, in particular a star
• All computers communicate in the same way– They address data to one or more computers and
then transmit that data across the cable in the form of electronic signals
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Sending the Signal
• When a computer has data to send, it addresses that data, breaks it into manageable chunks, and sends it across the network as electronic signals– All computers on a logical bus receive them
• Only the destination accepts the data• All users must share the available amount of
transmission time– Thus, network performance is reduced
• A bus topology is a passive topology– In an active topology network, computers and other
devices regenerate signals and are responsible for moving data through the network
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2.3. Physical Ring Topology
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2.4. Logical Ring Topology
• Data in a logical ring topology travels from one device, or node, on the network to the next device until the data reaches its destination– Token passing is one method for sending data
around a ring
• Modern logical ring topologies use “smart hubs” that recognize a computer’s failure and remove the computer from the ring automatically
• An advantage of the ring topology lies in its capability to share network resources fairly
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2.5. Physical Star Topology
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2.5.1. A Logical Bus Implemented as a Physical Star
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2.5.2. A Logical Ring Implemented as a Physical Star
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2.5.3. Switching Implemented as a Physical Star
• Switching is neither a bus nor a ring logically, but is always implemented as a physical star– A switch takes a signal coming from a device
connected and builds a circuit on the fly to forward the signal to the intended destination computer
– Superior to other logical topologies because, unlike bus and ring, multiple computers can communicate simultaneously without affecting each other
– Dominant method used in almost every LAN design
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2.6. Wireless Topologies
• Wireless networking has a logical and physical topology– Ad hoc topology: two computers can communicate
directly with one another; sometimes called a peer-to-peer topology
– Infrastructure mode: Use a central device, called an access point (AP), to control communications
• Star physical topology because all the signals travel through one central device
• Logical bus topology
3. Examining Variations of Physical Topologies
3.1. Extended Star Topology
3.2. Mesh Topology
3.3. Combination Star Bus Topology
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• The major physical topologies have three typical variations or combinations– Extended star– Mesh– Combination star and bus
• These combinations can be used to get the most from any network
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3.1. Extended Star Topology
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3.2. Mesh Topology
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3.3. Combination Star Bus Topology
4. Hubs and Switches
4.1. Hubs
4.2. Switches
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• Both hubs and switches can act as the center of a star topology
• Basic operation was discussed briefly; this section expands on them
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4.1. Hubs
• In everyday use, a hub is “the center of activity”– This definition is appropriate in network usage also
• In network usage, there are a number of variations on this central theme– Active hub– Passive hub– Repeating hub (just a type of active hub)– Switching hub
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4.1.1. Active Hubs
• Most common type of hub today• Regenerate, or repeat, the signals
– Require electrical power to run• Generally, have many ports—eight or more• Also called multiport repeaters or repeating hubs
1. Takes a signal coming in on one port2. Cleans the signal (e.g., by filtering out noise)3. Strengthens the signal4. Sends the regenerated signal out to all other ports
• Drawback: require sharing the cable bandwidth among all connected stations
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4.1.2. Passive Hubs
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4.2. Switches
• Central connecting point in a star topology network
• Does more than simply regenerate signals
• Looks just like a hub, with several ports for connecting workstations in a star topology
• Determines to which port the destination device is connected and forwards the message to that port– This capability allows a switch to handle several
conversations at one time, thereby providing the full network bandwidth to each device rather than requiring bandwidth sharing
5. Constructing a Network Layout
5.1. Selecting a Topology
5.2. Creating the Layout
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• The first step in any network design is to evaluate the underlying requirements– First determine how the network will be used, which
often decides the topology you use– Decide the types of devices for interconnecting
computers and sites– Finally, the type and usage level of network
resources dictates how many servers you need and where to place servers
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5.1. Selecting a Topology
• Most new network designs come down to only one choice: How fast should the network be?
• The physical topology will certainly be a star, and the logical topology is almost always switching
• Ethernet switches are typically used on a LAN, but you might consider other logical topologies for other reasons:– Use of legacy equipment– Network size– Cost restrictions– Difficulty to run cables
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5.2. Creating the Layout
• Network must be documented– Useful questions before drawing the diagram
• How many client computers will be attached?• How many servers will be attached?• Will there be a connection to the Internet?• How will the building’s physical architecture
influence decisions, such as whether to use a wired or wireless topology, or both?
• Which topology or topologies will you use?– Network diagram must be kept up to date
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Summary
• Basic physical topologies: bus, star, or ring– Physical bus: easy to install but outdated
• The logical bus topology is still used, but is almost always implemented as a physical star
– Physical ring: connects devices in such a way that the cabling starts and ends with the same computer
• Rarely used (except in FDDI)• Logical ring topology typically uses token passing to
send data around ring; normally implemented as a star
– Physical star: centralized management and higher degree of fault tolerance
• Topology of choice in today’s networks
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• For wireless networks: ad hoc or infrastructure mode• Variations on major topologies
– Extended star (most widely used)– Mesh (most fault tolerant)– Combination star and bus
• Hub: central point of concentration for a star network– Can be active (if it regenerates the signals) or passive
• Switch: provides better performance than a hub– Device of choice in corporate star topology networks
• Network layout should be consistent and maintained accurately as the network changes
Chapter Summary
•Networks build upon one of three basic topologies
•Bus topology is easy to install but is outdatedtopology not used for new installations
•Star topology offers centralized managementand higher degree of fault tolerance since singlecable or computer failure does not affect rest ofnetwork
•Star topology is topology choice for today’snetworks
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• Ring topology offers computers equal time onnetwork, but network performance degradeswhen more computers are added
• Hub, a central point of concentration for starnetwork, passes electronic signals to network
• Active hub regenerates signals
• Passive hub simply passes signals along
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• Switch offers greater bandwidth and intelligence,providing significant performance advantagesover hubs
• Switches have become device of choice incorporate star topology networks
• Variations on major topologies allow greaterfault tolerance and flexibility
• Mesh is most fault tolerant of all networktopologies, allowing every computer tocommunicate with every other computer
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• Star bus or star ring combines centralizedmanagement of star and best of bus andring topologies
• Network layout should be consistent withexisting network and accurately maintainedas network changes
• Many third-party tools can assist in designand maintenance
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Bus 43
Star 44
Extended Star 45
Ring 46
Mesh 47