Cisco CCDP Certification Training ARCH  Designing Cisco Network Service Architectures

What's included ARCH CCDP Training Course?

Our Training includes:

• Over 29 hours of full-multi-media interactive training
• Simulated  Router and Switch Labs
• Cisco Book
• 24 x 7 learner support by expert mentors via chat for one year
• Available in CD-ROM format or Online
• Simulated Practice Exams
• We also offer Live Class Nationally and Live Boot Camps

Audience

The primary audiences for Building Scalalble Cisco internetworks are:

• Cisco Network administrators and technicians who are responsible for implementing or troubleshooting a multilayer switched network in an enterprise environment.
• CCNP and CCDP candidates
• CCIE candidates
• System Engineers, Account Managers, Channel Partner/Reseller

CCDP Prerequisites

To fully benefit from ARCH, students must have the following prerequisite skills and knowledge:

• Basic router configuration
• Basic switch configuration
• Basic VLAN configuration
• Spanning Tree Protocol configuration
• Inter-Switch Link configuration
• Standard access list configuration
• Cisco CCNA and CCDA Certifications

You will learn:

• Cisco AVVID framework and explain how it addresses enterprise network design needs for performance, scalability, and availability, discuss the Enterprise Composite Network Model and explain how it addresses enterprise network modularity, and discuss the major steps in the network design process and explain how to validate a network design.
• Plan effective Campus Infrastructure and Server Farm module designs, given specific enterprise network requirements
• Demonstrate the ability to design Enterprise Edge connectivity using classic WAN, Remote Access, and Internet Connectivity module types
• The concepts of, and recall the protocols used in, network management, demonstrate the ability to design appropriate network management services, and define an appropriate design architecture using Cisco strategies and solutions
• The necessary components of a high availability solution, given specific enterprise availability requirements
• Evaluate and identify enterprise network security policies and recommend strategies to improve enterprise network security, and to propose a security strategy for the Enterprise Campus and the Enterprise Edge functional areas using the Cisco SAFE blueprint, given specific security requirements
• Components of QoS and design scalable network QoS solutions
• Concept and operation of IP multicast, recall intradomain and interdomain protocols, and design IP multicast services for enterprise campus networks and WANs
• The key technologies that enable VPNs and demonstrate how to design site-to-site and remote-access VPNs
• Technologies that enable WLANs and illustrate design guidelines for WLAN implementation in enterprise networks
• The key technologies that enable IP telephony and illustrate design guidelines for networks that support IP telephony

ARCH Training Content

1.) Enterprise Design and the Cisco AVVID Framework

• identify the key performance, scalability, and availability considerations when deploying an enterprise network.
• relate how the AVVID intelligent network services and network solutions address the requirements of enterprise networks.
• recognize the advantages of the Enterprise Composite Network Model when compared with the hierarchical model of network design.
• associate the appropriate module and submodule in the Enterprise Composite Network Model with its specific function.
• recall an effective network design process for the Enterprise Campus functional area.
• distinguish between the three primary phases of the network design process and identify the steps involved in validating a network design.

2.) The Design of Cisco Enterprise Campus Networks

• determine the appropriate logical and physical network segments and segmentation strategies in a given campus network infrastructure.
• determine the appropriate transmission media, data-link protocols, and spanning-tree strategy in a given campus network infrastructure.
• distinguish between Layer 2 and Layer 3 switching and determine which is the most appropriate for the individual submodules of the Campus Infrastructure module.
• recognize the considerations involved in identifying an IP addressing strategy for the campus network.
• select routing protocols to meet campus network requirements.
• recognize suitable network designs for sample small, medium, and large campuses.
• select the most effective Server Farm module design.
• determine a campus network design to meet the needs of a given scenario.

3.) The Design of Cisco Enterprise Edge Connectivity

• identify the modules and typical requirements for the Enterprise Edge functional area, and recognize the design steps and traffic pattern considerations for it.
• identify WAN requirements for the campus network and recognize how to select an appropriate WAN topology and service provider.
• identify the criteria for selecting data-link layer technology, physical layer technology, and WAN features and be able to use the Product Advisor tool to select edge routing solutions.
• outline the considerations for selecting routing protocols and an IP addressing scheme for a site-to-site WAN.
• recognize the rationale for design decisions in a given example of an enterprise WAN design.
• design a site-to-site WAN solution to meet the requirements of a given Enterprise Edge network infrastructure.
• identify and distinguish between the requirements for Remote Access Connectivity and termination.
• recognize how to use the Product Advisor tool for selecting Cisco remote access routing solutions, and identify the rationale for remote access design decisions in given examples.
• design a remote access solution to meet the requirements of a given Enterprise Edge network infrastructure.
• identify the typical requirements for the Internet Connectivity module, recognize the main characteristics of NAT, and distinguish between the two methods of connecting to an ISP.
• design an Internet Connectivity solution to meet the requirements of a given Enterprise Edge network infrastructure.

4.) The Design of Cisco Network Management Services

• identify network management components and recognize appropriate strategies for developing network management policies, procedures, and methods.
• identify the components and features of CiscoWorks, and recognize the criteria for selecting CiscoWorks LAN and RWAN management tools.
• outline design considerations and deployment strategy guidelines for the Network Management module.
• identify the rationale for a selection of sample network management design decisions.
• design a network management services solution to meet the requirements of a given enterprise network.

5.) The Design of Cisco High Availability Services

• identify the enterprise requirements and components for high availability.
• identify the guidelines for when to implement fault-tolerant devices and redundant topologies.
• differentiate between the three spanning tree protocols - PVST, RSTP, and MST - and identify the main advantages of PortFast and UplinkFast.
• distinguish between redundancy options, identify carrier and environment considerations, and recognize best practices for high availability network design.
• identify the guidelines for designing a campus network and the Enterprise Edge for high availability.
• design a high availability solution to meet the requirements of a given enterprise network.

6.) The Design of Cisco Security Services

• associate a security risk level to the network systems and components in a given scenario.
• match security solutions to the specific types of network attack that they help mitigate.
• recognize the security features and functionality provided by specific firewall and Intrusion Detection System solutions.
• recognize the security features and services provided by specific authentication, authorization, and accounting solutions.
• recognize the security features and services provided by IPSec.
• state the best practice recommendations for maximizing security for devices, applications, and the network as a whole.
• identify an appropriate security strategy for small and medium network components, given specific security requirements.
• identify the design objectives of the Cisco SAFE architecture.
• identify an appropriate security strategy for large and Enterprise Edge network components, given specific security requirements.
• define a security services solution to meet the needs of a given enterprise network scenario.

7.) The Design of Cisco QoS Solutions

• identify the benefits gained from utilizing quality of service (QoS) technologies in an enterprise.
• distinguish between the Best-effort, Integrated Service, and Differentiated Service QoS architectures, and identify the classification and marking components of a Cisco QoS solution.
• distinguish between the congestion avoidance, congestion management, traffic conditioning, and link efficiency mechanisms of a Cisco QoS solution.
• differentiate between the QoS design guidelines for data, voice, and video applications.
• identify the QoS roles performed throughout an enterprise network.
• associate specific QoS tools with the appropriate modules in an enterprise network for a given data, application, and network scenario.
• determine the QoS design solution for a given enterprise network scenario.

8.) The Design of Cisco IP Multicast Services

• distinguish between the benefits and disadvantages of using IP multicast as an underlying transport mechanism in an enterprise network.
• recognize how multicast forwarding works with RPF and the main considerations for the use of IP multicast receiver group membership.
• recognize how the Protocol Independent Multicast (PIM) for IP multicast operates and the advantages and disadvantages of its different modes.
• recommend the most efficient method to control IP multicasting in a Layer 2 switching environment for a given scenario.
• identify the design considerations for IP multicast implementations in an enterprise.
• recommend an appropriate design for IP multicast services in small and large enterprise networks, and over a WAN.
• determine an IP multicast solution to meet the requirements of a given enterprise network.

9.) The Design of Cisco Virtual Private Networks

• list the attributes of VPN, define VPN tunneling, and identify the primary security technologies for VPN.
• list the capabilities offered by scalable VPN concentrators and identify the features that a VPN management solution should support.
• list the considerations for resiliency and high availability, identify key components, and sequence the steps for the design of site-to-site VPNs.
• identify design considerations for routing protocol, packet fragmentation, and IPSec security for site-to-site VPNs.
• outline some site-to-site VPN designs.
• identify the advantages and design considerations of a remote-access VPN.
• list the steps in capacity planning for a remote-access VPN and identify issues with NAT.
• outline example designs for remote-access VPNs.
• define a VPN solution to meet the requirements of a given enterprise network.

10.) The Design of Cisco Enterprise Wireless Networks

• define WLAN architecture and how WLANs meet enterprise requirements, and define the IEEE 802.11 standards and the components of a Cisco wireless solution.
• identify WLAN throughput and coverage factors.
• identify issues that affect the implementation of WLAN solutions.
• identify roaming, multicast, and QoS considerations for WLANs, and distinguish between the WLAN security extensions.
• identify security strategies for wireless networks using Extensible Authentication Protocol (EAP) and Virtual Private Networks (VPNs).
• define small office, enterprise, and remote access WLAN design models.
• define a wireless LAN solution to meet the requirements of a given enterprise network.

11.) The Design of Cisco IP Telephony Solutions

• identify the components of a Cisco IP telephony solution, and define CallManager and its deployment models.
• identify the transcoder, conferencing, and application components of the Cisco IP telephony solution.
• identify design considerations for Cisco CallManager clusters.
• identify single-site IP telephony solution benefits and best practices.
• identify multisite IP telephony solution benefits and best practices.
• describe the deployment of the distributed call processing model.
• identify the best practices for design models for clustering over the IP WAN.
• define the physical network design considerations and bandwidth provisioning to support a Cisco IP telephony solution.
• recognize the traffic engineering process and identify dial plan design considerations to support a Cisco IP telephony solution.
• identify network management models used for IP telephony and recognize the remote site survivability process.
• identify appropriate security and QoS measures for voice.
• define an IP telephony solution to meet the requirements of a given enterprise network.

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