Ccdp Cisco Internet Design (Paperback)

Introduction

Objective 1: Demonstrate an understanding of the steps for designing internetwork solutions
Objective 2: Analyze a client's business and technical requirements and select appropriate internetwork technologies and topologies
Objective 3: Construct an internetwork design that meets a client's objectives for internetwork performance, functionality, and cost
Objective 4: Define the goals of internetwork design
Objective 5: Define the issues facing designers
Objective 6: List resources for further information
Objective 7: Identify the origin of design models used in the course
Objective 8: Define the hierarchical model
Objective 9: List common reasons that customers invest in a campus LAN design project
Objective 10: Examine statements made by a client and distinguish the relevant issues that will affect the choice of campus LAN design solutions
Objective 11: Define switches, virtual LANs, and LAN emulation
Objective 12: Examine a client's requirements and construct an appropriate switched campus LAN solution
Objective 13: Define routing functions and benefits
Objective 14: Examine a client's requirements and construct an appropriate campus LAN design solution that includes switches and routers
Objective 15: Examine a client's requirements and construct an appropriate ATM design solution
Objective 16: Construct designs using ATM technology for high?performance workgroups and high?performance backbones
Objective 17: Upgrade internetwork designs as the role of ATM evolves
Objective 18: Choose the appropriate IP addressing scheme based on technical requirements
Objective 19: Identify IP addressing issues and how to work around them
Objective 20: Choose the appropriate IP routing protocol and features based on convergence, overhead, and topology
Objective 21: Identify IP routing pathologies and issues and how to avoid them
Objective 22: Use modular design and summarization features to design scalable Open Shortest Path First (OSPF) internetworks
Objective 23: Allocate IP addresses in contiguous blocks so that OSPF summarization can be used
Objective 24: Determine IGRP convergence time for various internetwork configurations
Objective 25: Use IGRP for path determination in IP internetworks
Objective 26: Use Enhanced IGRP for path determination in internetworks that support IP, IPX, and AppleTalk
Objective 27: Examine a client's requirements and construct an appropriate AppleTalk design solution
Objective 28: Choose addressing and naming conventions to build manageable and scalable AppleTalk internetworks
Objective 29: Use Cisco IOS TM features to design scalable AppleTalk internetworks
Objective 30: Examine a client's requirements and construct an appropriate IPX design solution
Objective 31: Choose the appropriate routing protocol for an IPX internetwork
Objective 32: Design scalable and manageable IPX internetworks by controlling RIP and SAP traffic
Objective 33: Examine a client's requirements and construct an appropriate NetBIOS design solution
Objective 34: Design a source?route?bridged internetwork that provides connectivity for NetBIOS applications and controls NetBIOS explorer traffic
Objective 35: List common concerns that customers have about WAN designs
Objective 36: Examine statements made by a customer and distinguish issues that affect the choice of WAN designs
Objective 37: Design core WAN connectivity to maximize availability and optimize utilization of resources
Objective 38: Design a full or partial mesh Frame Relay non?broadcast multi?access (NBMA) core for full or partial connectivity
Objective 39: Choose a scalable topology for NBMA Frame Relay
Objective 40: Use subinterface Frame Relay configurations to design robust core WANs
Objective 41: Design scalable internetwork WAN non?broadcast multi?access X.25
Objective 42: Design scalable, robust internetwork WANs with an X.25 subinterface configuration
Objective 43: Use X.25 switching to provide X.25 service over an integrated IP backbone
Objective 44: Explain ISDN services
Objective 45: Examine a customer's requirements and recommend appropriate ISDN solutions
Objective 46: Construct an ISDN design that conserves bandwidth and is cost?effective
Objective 47: Examine a client's requirements and recommend appropriate point?to?point and asynchronous WAN solutions
Objective 48: Choose appropriate link encapsulation for point?to?point circuits
Objective 49: Discuss the hierarchical and connection?oriented nature of SNA
Objective 50: Describe the use of gateways to attach Token Ring devices to an SNA network
Objective 51: Explain how LLC2 and SDLC sessions are established
Objective 52: Describe reasons for integrating SNA technology with internetworking technology
Objective 53: Examine a client's requirements and recommend SNA internetworking solutions
Objective 54: Construct SNA designs that replace legacy communications equipment with multiprotocol routers
Objective 55: Build redundancy into SNA internetworks
Objective 56: Design remote source?route bridged SNA internetworks in full and partial mesh configurations
Objective 57: Choose the appropriate place to do priority queuing or custom queuing for SNA
Objective 58: Examine a client's security requirements and recommend firewalls and gateways
Objective 59: Design a firewall system using packet?filtered routers and bastion hosts
Objective 60: Choose protocols to be filtered on routers in the firewall
Objective 61: Summarize the major concepts covered in this class
Objective 62: Recall the steps for internetwork design
Objective 63: Describe methods for monitoring your internetwork design
Objective 64: Return to your environment with fresh ideas and plans for internetwork designs

Index