Equipment List

Timed Portion

Lab Rules

• No static routes or floating static routes are used unless specifically stated.

• Follow the instructions exactly. Be careful to propagate routes only where and when instructed. Use the PVCs only as directed by the instructions.

• Primary configurations might need to be modified for Part II only when you are finished with the primary configurations.

• You can use the configuration guides and the Cisco Documentation CD-ROM for your only reference material.

• You have 8 1/2 hours to complete the lab. Do not talk to anyone during this phase.

• It is recommended that you read the entire lab before beginning.

• Make an accurate and precise network illustration.

• Use Figure 18-6 as reference for the physical layout of the lab.

Section I: Basic IP Configuration

1. Access server: Configure the access server/router so that all the routers and the switches can be accessed through reverse Telnet. Password-protect all routers and switches with the password cisco.

2. IP address assignment: Assign an IP addresses to all physical interfaces, as denoted in Figure 18-6. Use the major network of 165.10.x.x on all interfaces. Use a 24-bit mask on all interfaces except for the following:

   R1: Use a 30-bit address on the HDLC link between R1 and R2.

   R2: Assign an IP address of 172.16.1.1/24 to a loopback interface.

   R4: Assign the IP address of 165.10.10.1 to the Ethernet interface. Assign an IP address of 200.128.1.1/24 to a loopback interface.

   R8: Assign the IP address of 10.10.10.1/24 to the Token Ring interface.

3. Full IP and IPX connectivity to all Ethernet, Token Ring, and loopback interfaces will be expected unless noted.

4. Document the network thoroughly; include all OSPF areas, IP/IPX address, IPX networks, and so forth.

Section II: Catalyst/LAN Configuration

1. Configure the VLANs as depicted in Figure 18-6. R1, R3, and R6 reside on VLAN 1, while VLAN 2 resides on R4. Configure the Token Ring segments at this time. Assign the management interface of the token ring switch the IP address of 10.10.10.10.

2. Configure a full-duplex , ISL trunk on port 1/1. Set Spanning Tree so that the root for VLAN 2 is always your switch. You might or might not have another switch to connect to in this lab. This will not impact your configuration.

3. Configure VTP, such that VTP updates will be listened to and forwarded, but not used to update the VLAN database.

Section III: OSPF and Frame Relay Configuration

1. Configure the Frame Relay network as shown on Figure 18-6.

2. R2, R3, and R4 should share the same IP subnet; configure OSPF Area 10 between the routers.

3. Configure VLAN 1 to be in OSPF Area 0. Configure R2's Ring 2 in Area 100. Configure the HDLC link between R1/R2 to be in Area 30.

4. Configure Type II Authentication between R1 and R2. Use lbu as the password.

5. Log any OSPF adjacency changes on the backbone area.

Section IV: Routing Protocols and Redistribution

1. Configure IGRP on VLAN 2 and on the Frame Relay circuit between R4/R8; use 2010 as the Autonomous System ID. Ensure full IP reachability to the OSPF network.

2. Configure the PPP backup link on R4/R8 to become active only upon loss of Frame Relay service. The PPP link should pass all routes; you may not use a static route for this.

3. Prevent the route of the Token Ring network on R8 from reaching R4 The ISDN should not excessively dial and only work during a loss of Frame Relay service.

Section V: ISDN Configuration

1. Configure the ISDN interfaces on R4 and R6. Be sure that you can ping the R4/R6's ISDN interfaces before moving on.

2. Configure CHAP authentication on the ISDN link. Use ccie as the password.

3. Configure the ISDN interfaces as part of the OSPF domain. Put the interfaces in OSPF Area 20. The ISDN should not excessively dial and work only during a loss of Frame Relay service.

Section VI: IPX Configuration

1. Configure IPX on VLAN 1, VLAN 2, Ring 2, and Ring 8.

2. Configure IPX EIGRP on R1, R2, R3, and R6. Create a tunnel from R3 to R4 across the Frame Relay network. Ensure that all the IPX networks are visible on all routers.

3. Configure IPX RIP/SAP between R4 and R8 across the Frame Relay network. Make IPX traffic from R4 to R8 use a separate PVC from IP traffic.

4. Configure IPX SAP on Ring 2, which supports print services. This SAP is called fakeprint and has socket 451. Ensure that R4 can see this SAP.

5. Apply a static SAP to R6 that is three hops away. The SAP offers print services and should be configured as such.

Section VII: Bridging

1. Transparently bridge SNA from VLAN 1 to VLAN 2 across the Frame Relay network. Make R4 the root of the Spanning Tree.

2. Bridge and route IPX on VLAN 2 of R4.

Section VIII: Miscellaneous Cisco IOS Software Configuration

1. Configure custom queuing on R4 with the following guidelines: EIGRP, OSPF, and IPX traffic have an average packet size of 500 and need 25 percent of the link. WWW traffic has an average packet size of 1412 and will get 10 percent of the link. The average packet size for the default queue is 700 and will get 65 percent of the link. Assign the queue the Frame Interface.

2. The subnet 10.10.10.0/24 on R8 should not be circulated by any routing protocol. There are two hosts on this network, 10.10.10.5 and 10.10.10.10. These hosts need full reachability to the lab network. Allow these two hosts to have the same IP address each time they are translated.

3. A mainframe resides on VLAN 2. It has three IP addresses; 165.10.10.100, 165.10.10.101, and 165.10.10.102. These IP addresses correspond to a single MAC address of 2200.0001.0001. Configure the router, R4, to support forwarding traffic to the single MAC address for all three IP addresses.