Chapter 1-10 Labs
Chapter 1: Overview of Scalable Networks
Labs:
1.4.1 This lab introduces the CCNP lab equipment and some IOS features that might be new to you. This introductory activity also describes how to use a simple text editor to create all (or part) of a router configuration file. After you create a text configuration file, you can apply that configuration to a router quickly and easily by using the techniques described in this lab.
1.4.2 This activity describes how to capture HyperTerminal and Telnet sessions.
1.4.3 This lab activity reviews the basics of standard and extended access lists, which are used extensively in the CCNP curriculum.
1.5.1 In this lab, you observe equal-cost load balancing on a per-packet and per-destination basis by using advanced debug commands.
1.5.2 In this lab, you observe unequal-cost load balancing on an IGRP network by using advanced debug commands.
Chapter 2: IP Addressing 
Labs:
2.10.1 In this lab, you configure VLSM and test its functionality with two different routing protocols, RIPv1 and RIPv2. Finally, you use IP unnumbered in place of VLSM to further conserve addresses.
2.10.2.1 In this lab, you create an addressing scheme using variable-length subnet masking (VLSM).
2.10.2.2 In this lab, you create an addressing scheme using variable-length subnet masking (VLSM).
2.10.2.3 In this lab, you create an addressing scheme using variable-length subnet masking (VLSM).
2.10.3 In this lab, you configure a Cisco router to act as a DHCP server for clients on two separate subnets. You also use the IP helper address feature to forward DHCP requests from a remote subnet.
Interactive Labs:
2.8.3 In this lab activity you will configure SanJose2 to act as a DHCP server. Then you will configure SanJose1 to forward UDP broadcasts for DHCP requests.
Finally, you will test your configuration using a DHCP client.
Chapter 3: Routing Overview
Labs:
3.6.1 In this lab, you configure RIPv2 and then EIGRP so that you can compare their metric calculations.
3.6.2 In this lab, you configure IGRP for unequal-cost load balancing and tune IGRP's timers to improve performance.
3.6.3 In this lab, you configure a default route and use RIP to propagate this default information to other routers. When you have this configuration working, you must migrate the network from RIP to IGRP and configure default routing to work with that protocol as well.
3.6.4 In this lab, you configure a floating static route.
Chapter 4: OSPF 
Labs:
4.6.1 In this lab, you configure OSPF on three Cisco routers. First, you configure loopback interfaces to provide stable OSPF Router IDs. Then you configure the OSPF process and enable OSPF on the appropriate interfaces. After OSPF is enabled, you tune the update timers and configure authentication.
4.6.2 In this lab, you observe the OSPF DR and BDR election process using debug commands. Then you assign each OSPF interface a priority value to force the election of a specific router as a DR.
4.6.3 In this lab, configure OSPF as a point-to-multipoint network type so that it operates efficiently over a hub-and-spoke Frame Relay topology.
Interactive Labs:
4.3.1 In this lab exercise you will configure the SanJose1 router for OSPF in a single area. The Westasman router is already configured for OSPF. You will first specify the OSPF process ID and then enter router configuration mode. In router configuration mode, you will configure OSPF for specific networks in area 0.
Chapter 5: Multiarea OSPF
Labs:
5.8.1 In this lab, you configure multiarea OSPF operation, interarea summarization, external route summarization, and default routing.
5.8.2 In this lab, you configure an OSPF stub area and a totally stubby area.
5.8.3 In this lab, you configure an OSPF NSSA in order to import external routing information while retaining the benefits of a stub area.
5.8.4 In this lab, you configure an OSPF virtual link so that a disconnected area can reach the backbone, as required by OSPF.
5.9.1 In this lab, you create a multiarea OSPF autonomous system that includes a totally stubby area and a persistent default route toward the ISP.
Interactive Labs:
5.3.1 The purpose of this activity is to configure an Area Border Router in a multiarea OSPF environment. SanJose1 and the Singapore routers have already been configured for OSPF routing. Your task is to configure SanJose3 to enable Inter-Area routing.
5.5.3 The purpose of this activity is to configure an OSPF virtual link so that the disconnected Area 3 can reach the backbone Area 0, as required by OSPF. Although Multi-Area OSPF has already been configured, you will configure a virtual link through Area 51 connecting Area 3 to the backbone Area 0.
Chapter 6: EIGRP
Labs:
6.7.1 In this lab, you configure both EIGRP and IGRP within the International Travel Agency WAN and observe the automatic sharing of route information between both protocols.
6.7.2 In this lab, you configure EIGRP over a full-mesh topology so that you can test and observe DUAL replace a successor with a feasible successor after a link failure.
6.7.3 In this lab, you configure EIGRP to test its operation over discontiguous subnets by disabling automatic route summarization. Then you manually configure EIGRP to use specific summary routes.
6.8.1 In this lab, you configure an International Travel Agency EIGRP WAN link with one IGRP segment within the same autonomous system. You also use EIGRP interface summarization to reduce the number of routes in an EIGRP routing table.
Interactive Labs:
6.5.1 In this lab exercise you will configure EIGRP on the Singapore router. The SanJose3 router is already configured for EIGRP.
Chapter 7: Route Optimization
Labs:
7.5.1 In this lab, you configure a combination of advanced routing features to optimize routing. These features include distribute lists, passive interfaces, default routes, and route redistribution.
7.5.2 In this lab, you apply a routing policy by configuring a route map.
7.5.3 In this lab, you configure mutual redistribution between RIPv1 and OSPF.
7.6.1 In this challenge lab, you create and optimize a network utilizing RIPv2 and OSPF.
Interactive Labs:
7.3.9 The purpose of this lab exercise is to configure mutual redistribution between RIP and OSPF on SanJose1.
Chapter 8: BGP
Labs:
8.8.1 In this lab, you configure BGP to exchange routing information with the two Internet service providers (ISPs).
8.8.2 In this lab, you configure both IBGP and EBGP. In order for IBGP peers to correctly exchange routing information, you must also use the next-hop-self and aggregate-address commands.
8.8.3 In this lab, you use BGP commands to prevent private AS numbers from being advertised to the outside world. You also use the AS_PATH attribute to filter BGP routes based on their source AS numbers.
8.8.4 In this lab, you use the LOCAL_PREF and MED attributes to modify BGP's behavior and implement routing policy.
Interactive Labs:
8.3.2 In this lab, you will configure the SanJose3 router for BGP and verify its operation using show commands. All routers have been already configured for IP. The ISP routers are running BGP.
8.3.3 The purpose of this activity is to configure both IBGP and EBGP sessions on the ISP1 router. All other routers have already been configured for BGP.
Chapter 9: Scaling BGP
Labs:
9.7.1 In this lab, you configure IBGP routers to use a route reflector and a simple route filter.
9.7.2 In this lab, you use the COMMUNITIES attribute to enforce routing policy.
9.7.3 In this lab, you use BGP peer groups to simplify your configuration tasks.
9.8.1 Configure EBGP between the company's core routers and the two ISP routers, and configure IBGP with peers to create a network that will provide the International Travel Agency with a fully meshed, reliable, and efficient core network.
Interactive Labs:
9.1.4 In this lab you will configure IBGP routers to use ISP-B as a route reflector to work around IBGP's full-mesh requirements. All routers are already configured for IP and RIP. IBGP peer information has also been configured on all routers.
Chapter 10: Security
Labs:
10.7.1 In this lab, you configure a dynamic access list for lock-and-key security.
10.7.2 In this lab, you configure a reflexive access list to implement IP session filtering.
10.7.3 In this lab, you configure content-based access control (CBAC) to secure an internal network and allow limited outside access to a DMZ.
Interactive Labs:
10.1.2 In this lab you will configure the SanJose1 router to allow traffic on TCP port 80 (web traffic) only.
You will first create a named access list that will permit web traffic from any from the Internet to the destination 192.168.1.0/24 network, but deny all other IP services.
In interface configuration mode, you will apply the named access list to interface Serial 0/0.