Cisco 3 - Switches

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Module 5

Switches

Cisco 3 - Switches

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Module 5

NOTE:

The following is Cisco’s logical idea of planning a LAN.

Their design is an approach but not the only one.

Medium & smaller companies will depend on the ideas of their people to come up with design criteria – this is where the Cisco planning criteria can be used.

This chapter will give additional requirements & suggestions for your LAN design.

Cisco 3 - Switches

Perrine - Brierley Page 304/18/23

Module 5

First step in designing a LAN

• establish & document the goals of the design. It is based on:

• functionality –design must meet the job requirement – must work; connectivity with reasonable speed & reliability

• scalability – initial design should grow without any major chances to overall design

• adaptability – design toward the future (Frame Relay over ATM; SMDS, Switched Multi-megabit Data Service, to ATM)

• manageability – design to facilitate network monitoring & management

Inter-network design seeks to provide the greatest availability for the least cost.

Cisco 3 - Switches

Perrine - Brierley Page 404/18/23

Module 5

One needs to consider the following in overall LAN design:

• function & placement of servers

• collision detection

• place devices to reduce the collision

• contention refers to excessive collisions on Ethernet caused by too many devices

• segmentation

• use bridges, switches & routers to separate collision domains

• note for bridges & switches; don’t forward collisions, but still belong to the broadcast domain

• bandwidth vs. broadcast domains

• bandwidth domain is everything associated with one port on a bridge /switch. All workstations within one bandwidth domain compete for the same LAN bandwidth resource.

Cisco 3 - Switches

Perrine - Brierley Page 504/18/23

Module 5

Under segmentation: bridges & switches are used

• results in multiple collision domains

• still a single broadcast domain

Bandwidth domain is everything associated with one port on a bridge or switch.

For Ethernet switches, a bandwidth domain is also known as a collision domain.

Cisco 3 - Switches

Perrine - Brierley Page 604/18/23

Module 5

Cisco’s design methodology:

1) Gather the users’ requirements & expectations

• organization’s history• operational policies• what their business is• who has the authority to make decisions on network changes

2) Analyze requirements

• what are the voice & data requirements; which is in more demand; affects bandwidth

• requirements of the users

3) Design the layer 1,2,3 i.e. topology• type of topology – star, extended star (most common; 802.3)• cabling ( TIA/EIA-568-A); UTP; FIBER• type of cabling determines the distance of the catchment area

4) Document the logical & physical network implementation

Cisco 3 - Switches

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Module 5

Servers:

Two distinct classes:

• enterprise server –

• supports all the users on the network by offering services (e-mail, DNS)

• placed in the MDF

• workgroup server –

• applications for users

• placed in the IDF

Cisco 3 - Switches

Perrine - Brierley Page 804/18/23

Module 5

Cisco: between the MDF and IDF, the layer 2 LAN switches should have 100 Mbps or more allocated for these servers.

Intranet versus the internet is that the public does not have access to the organization intranet.

When layer 2 bridges or switches are used for segmentation, they create separate collision domains, and hence increase bandwidth to individual stations.

A bandwidth domain is everything associated with one port on a bridge or switch.

Cisco 3 - Switches

Perrine - Brierley Page 904/18/23

Module 5

MDF – Main Distribution Facility

• HCC – Horizontal cross-connect

Wiring closet where the horizontal cabling connects to a patch panel that is connected by backbone cabling to the MDF

IDF – Intermediate Distribution Facility

Used when a second wiring closed is needed because the hosts are outside of the 100 meter limit. Multiple catchment areas are formed. The IDF is connected to the MDF.

IDF is connected to the MDF by using vertical cabling, also called the backbone cabling

• VCC – Vertical cross-connect

Is used to interconnect the various IDFs to the central MDF.

Fast Ethernet, cooper wire ( 100Base-TX) & fiber-optic (100Base-FX) is used to connect the MDF to the IDF.

Cisco 3 - Switches

Perrine - Brierley Page 1004/18/23

Module 5

Layer 2 devices, bridges/switches purposes in the network is to provide:

• flow control

• error detection

• error correction

• reduce congestion

Cisco 3 - Switches

Perrine - Brierley Page 1104/18/23

Module 5

Asymmetric Switching / Symmetric Switching

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10 Mbps

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10 Mbps

100 Mbps

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Cisco 3 - Switches

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In a pure switched LAN environment, the size of the collision domain is two hosts.

Routers allows for segmentation of the LAN into unique physical & logical networks. Routers provide scalability because they can serve as firewalls for broadcasts.

Cisco 3 - Switches

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3-layer Model

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Core

Distribution

Access

Other sites/Internet

Campus Backbone

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Cisco 3 - Switches

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3-layer Model Core

Core

• implemented as WAN

• doesn’t perform any packet manipulation

• no ACLs, nor filtering

• were redundant paths are established

• load sharing & rapid convergence of routing protocols

• efficient use of bandwidth

Other sites/Internet

Cisco 3 - Switches

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3-layer Model Distribution

Core

Distribution

• demarc between access & core layers

• ACLs are added; filtering; packet manipulation

• VLAN routing

• workgroup access to the core layer

• broadcast/multicast domain definition

• policy-based connectivity (what is acceptable traffic)

• where remote sites have access

• security

Building backbone

Campus backbone

Cisco 3 - Switches

Perrine - Brierley Page 1604/18/23

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3-layer Model Access

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Access

• where local end users have access to network

• shared bandwidth

• switched bandwidth

• MAC-layer filtering

• microsegmentation

• isolate broadcast traffic from the workgroup

• ACLs & filtering

• LAN

• logical segmentation into functions

Cisco 3 - Switches

Perrine - Brierley Page 1704/18/23

Module 5

Server Placement

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Enterprise Server

Too much traffic for router 1 when enterprise server placed at access layer.

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Core

Distribution

Access

Cisco 3 - Switches

Perrine - Brierley Page 1804/18/23

Module 5

Server Placement

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Enterprise Server

Less traffic for router 1 when enterprise server placed at distribution layer.

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Distribution

Access

Cisco 3 - Switches

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Module 5

Server Placement

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Workgroup Server

Workgroup server is placed at access layer of site where the largest concentration of users are located.

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Cisco 3 - Switches

Perrine - Brierley Page 2004/18/23

Module 5

Enterprise servers are placed at the highest layer in the hierarchy.

Workgroup servers are placed nearest to the group that is using it.

Cisco 3 - Switches

Perrine - Brierley Page 2104/18/23

Module 5

Cisco suggests the following equipment for physical design:

• core (routers)

• 12000

• 7500

• 7200

• 7000

• distribution (routers)

• 4500

• 4000

• 3600

• access (routers)

• 2600• 2500• 1700• 1600