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This is one of the GNS3 topologies which we’ll configure as part of this course.

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This GNS3 topology is utilizing the GNS3 VM

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and I’ve loaded IOSvL2 images to the GNS3 VM

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In addition I am using a Cisco IOS router image

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also running within the GNS3 VM

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and I have that image available on both the local GNS3 server

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in other words running within Windows as well as on the GNS3 VM

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Under edit I am going to preferences and I’ve configured an image

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running on the local serveras well as the GNS3 VM

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You don’t have to configure the image in both places

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I’ve just done that for a various demonstrations in the Course

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I’ve also got an NPM server which I’ll use to manage this network using SNMP

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I’ll configure the various parts of this network throughout the course

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but at the end of the course

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I’ll have all of these videos together in one place

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so if you want to watch all of the config in a one go you can do that

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Now don’t worry too much if you don’t know all the terms

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that I am going to be using in this explanation

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We’ll be discussing this throughout the course

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but this topology gives us a nice scenario

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to build upon and shows you how the different technologies

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that we’re learning about can be implemented in a proper network

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In this topology we have 2 core switches

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as well as 2 access switches

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but pretend that we have more than 2 access switches

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Configuring more than 2 is kind of redundant

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in what we're doing here but I'll perhaps

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extend this topology and make it more complex

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to show you a larger topology as part of this scenario

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Various things need to be configured in this network

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we have to configure IP Addressing

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we have to confugure VLANs

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we have to configure VTP or VLAN Trunking Protocol

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We've got to configure Inter-VLAN routing

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between the various IP Addresses

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We've got to configure links such as these as trunk ports

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these links Gigabit02 on the Access Switch

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needs to be configured as Access Ports

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the reason why is that

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this router, router1 is going to be configured in VLAN10

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and is going to act as a host in the network

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so we're actually using a Cisco IOS image

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but it's going to mimic a host device

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tha same with this router which is going to be

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configured in VLAN20

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So this will also act as a PC in our topology

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Router2 is acting like PC2 in our topology

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but ratehr than using PCs to do this

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I want to show you how to configure routers

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with static routes and various other options

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to enable connectivity in the network

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Router3 is going to act as our gateway to the outside world

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so this router will be configured with NAT or Network Address Translation

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and an actual fact it will be using Port Address Translation or PAT

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to NAT these routers acting as PCs

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unto the Internet so that they can access

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sites such as Google.com and others

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This topology is gonna run as a Layer2 topology

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so we need to configure Spanning Tree

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Spanning Tree is enabled by default on Cisco Switches

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In this example we want to optimize

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Spanning Tree so we will configure PVST

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with this switch as the root for VLAN1 and VLAN10

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and this switch has the root for VLAN20

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so Router2 acting as PC2 is gonna send traffic to the core

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using this uplink whereas Router1

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acting as PC1 is gonna sent traffic to the core using this uplink

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We also have to think about the default gateways

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If Router1 acting as PC1 has Switch1 as its default gateway

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Switch1 will only be able to do

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Inter-VLAN Routing for Router1 or PC1 when it's up

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However if Switch1 goes down this PC

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will no longer be able to ping PC2

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or be able to access the Internet

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So we're going to want to implement

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HSRP or Hot Standby Routing Protocol

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to ensure that the default gateways of the PCs

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is in our topology are still available

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when one of the switches go down

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so we will configure HSRP for our user PCsin this topology

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sio that they can continue working

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even when one of the core switches goes down

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This toplogy have redundancy in it

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but Spanning Tree will block ports

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to stop loops in the topology

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and may stop ports that you least expects

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So we need to optimize Spanning Tree

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but not only making Switch1 the root for some VLANs

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and Switch2 the root for other VLANs

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But we also want to enable Link Aggregation or EtherChannel

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on these 2 core links

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Spanning Tree is gonna block one of this ports

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which negates the purpose of having

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multiple ports in the core between our core switches

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so we're gonna want to bond these 2 links together in the Link Aggregation

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Once we've configured the network

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we'll test connectivity between PC1 and PC2

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and will test failover to ensure

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that our network provides redundancy

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when one of the switches in the core goes down

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we'll also as mentioned test connectivity to the Internet

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and thus we will need to enable a NAT on Router3

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we will also need to enable Routing Protocols on our routers

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and inject a default route from Router3

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So we'll need to enable OSPF or EIGRP

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on our core devices and then advertise

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the default Internet route from Router3

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to both core switches

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We'll also need to enable Simple Network Management Protocol or SNMP

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on our switches so that Network Performance Monitor

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can manage the network

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In addition we're gonna want to use a syslog server

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to sent or restore our log information

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so we'll use NPM to receive syslog messages

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from our devices

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I'll include link to load a video

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where you can load a free trial version

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of Network Performance Monitor

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So there's a lot to do to get this topology to work

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I'll explain the configuration as I am going through this

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but for the basic theory please refer to the

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relevant modules in the course

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So lots to do. Let's get started configuring this topology