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Chapter 1: Analyzing The CiscoAnalyzing The Cisco Enterprise Campus Architecture
CCNP SWITCH: Implementing IP SwitchingCCNP SWITCH: Implementing IP Switching
© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco PublicCourse v6 Chapter #
1
Chapter 1 Objectives
Describe common campus design options and how design choices affect implementation and support of a campus LAN. Describe the access, distribution, and core layers.
D ib ll di d l t k Describe small, medium, and large campus network designs. Describe the prepare, plan, design, implement, operate,Describe the prepare, plan, design, implement, operate,
optimize (PPDIOO) methodology. Describe the network lifecycle approach to campus design.
Chapter #2© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Introduction to E t iEnterprise Campus Network Designg
Chapter #3© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Enterprise Network
Core (Backbone) CampusCampus Data Center Branch WAN Internet Edge
Chapter #4© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Regulatory Standards (U.S.)
There may be several legal regulations that have an impact on a network’s design. US regulations on networks include:
• Health Insurance Portability and Accountability Act (HIPAA)S b O l A t• Sarbanes-Oxley Act
• “Records to Be Preserved by Certain Exchange Members, Brokers and Dealers”: Securities and Exchange Commission (SEC) Rule 17a-44
Chapter #5© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Campus Designs
Modular - easily supports growth and change. Scaling the network is eased by adding new modules in lieu of complete redesigns. Resilient - proper high-availability (HA) characteristics
result in near 100% uptimeresult in near-100% uptime. Flexible - change in business is a guarantee for any
enterprise. These changes drive campus network p g prequirements to adapt quickly.
Chapter #6© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Multilayer Switches in Campus Networks
Hardware-based routing using Application-Specific Integrated Ci it (ASIC )Circuits (ASICs)
RIP, OSPF, and EIGRP are supported
Layer 3 switching speeds approximate that of Layer 2 switches
Layer 4 and Layer 7 switching supported on some switches
Future: Pure Layer 3 environment leveraging inexpensive L3 access layer switches
Chapter #7© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Cisco Switches
Catalyst 6500 Family – used in campus, data center, and core as well as WAN and branch• Up to 13 slots and 16 10-Gigabit Ethernet interfaces• Redundant power supplies, fans, and supervisor engines• Runs Cisco IOS Catalyst 4500 Family – used in distribution layer and in
collapsed core environments• Up to 10 slots and several 10-Gigabit Ethernet interfacesUp to 10 slots and several 10 Gigabit Ethernet interfaces• Runs Cisco IOS Catalyst 3560 and 3750 Families – used in fixed-port
scenarios at the access and distribution layersscenarios at the access and distribution layers Nexus 2000, 5000, and 7000 Families – NX-OS based
modular data center switches
Chapter #8© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Multilayer Switching Miscellany
ASIC-based (hardware) switching is supported even
Catalyst 6500 switches with a Supervisor Engine 720 and
with QoS and ACLs, depending on the platform; 6500 switches support
a Multilayer Switch Feature Card (MSFC3) must software-switch all packets
hardware-based switching with much larger ACLs than 3560 switches.
requiring Network Address Translation. Unlike CPUs, ASICs scale in
ASICs on Catalyst switches work in tandem with ternary content addressable memory
Unlike CPUs, ASICs scale in switching architectures. ASICs integrate onto individual line modules ofcontent addressable memory
(TCAM) and packet-matching algorithms for high-speed switching
individual line modules of Catalyst switches to hardware-switch packets in a distributed manner
Chapter #9© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
switching. distributed manner.
Traffic Types
Network Management – BPDU, CDP, SNMP, RMON, SSH traffic (for example); low bandwidth IP Telephony – Signaling traffic and encapsulated voice traffic;
low bandwidth IP Multicast – IP/TV and market data applications; intensiveIP Multicast IP/TV and market data applications; intensive
configuration requirements; very high bandwidth Normal Data – File and print services, email, Internet browsing,
d t b h d t k li ti l t didatabase access, shared network applications; low to medium bandwidth Scavenger Class – All traffic with protocols or patterns that
exceed normal data flows; less than best-effort traffic, such as peer-to-peer traffic (instant messaging, file sharing, IP phone calls, video conferencing); medium to high bandwidth
Chapter #10© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
g) g
Client-Server Applications
Mail servers File serversFile servers Database servers Access to applications is
fast, reliable, and secure
Chapter #11© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Client-Enterprise Edge Applications
Servers on the enterprise edge, exchanging data g g gbetween an organization and its public servers Examples: external mail Examples: external mail
servers, e-commerce servers, and public web servers Security and high
availability are paramountavailability are paramount
Chapter #12© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Service-Oriented Network Architecture (SONA)
Application Layer – business and collaboration applications; meet business requirements leveraging interactive services layer.I t ti S i L bl ffi i t ll ti f t Interactive Services Layer – enable efficient allocation of resources to applications and business processes through the networked infrastructure.
Networked Infrastructure Layer – where all IT resources interconnect.
Chapter #13© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Borderless Networks
Enterprise architecture launched by Cisco in October 2009. Model enables businesses to transcend borders, accessModel enables businesses to transcend borders, access
resources anywhere, embrace business productivity, and lower business and IT costs.F i t i i t l b l Focuses more on growing enterprises into global companies. Technical architecture based on three principles:Technical architecture based on three principles:
• Decoupling hardware from software• Unifying computation, storage, and network• Policy throughout the unified system
Provides a platform for business innovation. Serves as the foundation for rich media communications
Chapter #14© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Serves as the foundation for rich-media communications.
E t iEnterprise Campus Design
Chapter #15© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Building Access, Building Distribution, and Building Core LayersCore Layers
Building Core Layer: high-speed campus backbone p pdesigned to switch packets as fast as possible; provides high availability and adapts quickly to changes.
Building Distribution Layer: aggregate wiring closets and use switches to segment workgroups and isolate network problems.
Building Access Layer: grant user access to network devices.
Chapter #16© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Core Layer
Aggregates distribution layer switches. Implements scalable protocols and technologies and loadImplements scalable protocols and technologies and load
balancing. High-speed layer 3 switching using 10-Gigabit Ethernet. Uses redundant L3 links.
Chapter #17© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Distribution Layer High availability, fast path recovery, load balancing, QoS, and security Route summarization and packet manipulation Redistribution point between routing domains Packet filtering and policy routing to implement policy-based connectivity Terminate VLANs First Hop Redundancy Protocol
Chapter #18© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Access Layer High availability – supported by many hardware and software features, such
as redundant power supplies and First Hop Redundancy Protocols (FHRP).
Convergence – provides inline Power over Ethernet (PoE) to support IP telephony and wireless access points.
Security – includes port security, DHCP snooping, Dynamic ARP inspection, IP y p y, p g, y p ,source guard.
Chapter #19© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Small Campus Network
<200 end devices Collapsed coreCollapsed core Catalyst 3560 and 2960G switches for access layer Cisco 1900 and 2900 routers to interconnect branch/WAN
Chapter #20© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Medium Campus Network
200-1000 end devices Redundant multilayer switches at distribution layerRedundant multilayer switches at distribution layer Catalyst 4500 or 6500 switches
Chapter #21© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Large Campus Network
>2000 end users Stricter adherence to core, distribution, access delineationStricter adherence to core, distribution, access delineation Catalyst 6500 switches in core and distribution layers Nexus 7000 switches in data centers Division of labor amongst network engineers
Chapter #22© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Data Center Infrastructure
Core layer – high-speed packet switching backplane Aggregation layer – service module integration, default gateway
redundancy, security, load balancing, content switching, firewall, SSLoffload, intrusion detection, network analysis
Access layer – connects servers to network
Chapter #23© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
PPDIOO Lifecycle Approach toApproach to Network Designand ImplementationImplementation
Chapter #24© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
PPDIOO Phases
Prepare – establish organizational requirements. Plan – identify initial network requirements.Plan identify initial network requirements. Design – comprehensive, based on planning outcomes. Implement – build network according to design. Operate – maintain network health. Optimize – proactive management of network.
Chapter #25© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Lifecycle Approach
Lowering the total cost of network ownership
Developing a sound network design aligned
ith t h i lp
Increasing network availability I i b i ili
with technical requirements and business goals
Improving business agility Speeding access to
applications and services
Accelerating successful implementation Improving the efficiency ofapplications and services
Identifying and validating technology requirements
Improving the efficiency of your network and of the staff supporting it Reducing operating
Planning for infrastructure changes and resource requirements
Reducing operating expenses by improving the efficiency of operational processes and tools
Chapter #26© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
requirements processes and tools
Lifecycle Approach (1)
Benefits:• Lowering the total cost of network ownership• Increasing network availability• Improving business agility• Speeding access to applications and servicesp g pp Lower costs:
• Identify and validate technology requirements • Plan for infrastructure changes and resource requirements• Plan for infrastructure changes and resource requirements • Develop a sound network design aligned with technical requirements
and business goals • Accelerate successful implementation• Accelerate successful implementation • Improve the efficiency of your network and of the staff supporting it • Reduce operating expenses by improving the efficiency of operational
processes and tools
Chapter #27© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
processes and tools
Lifecycle Approach (2) Improve high availability:
• Assessing the network’s security state and its capability to support the proposed de-sign • Specifying the correct set of hardware and software releases, and keeping them opera-tional and current
P d i d i d i d lid i k i• Producing a sound operations design and validating network operations • Staging and testing the proposed system before deployment • Improving staff skills • Proactively monitoring the system and assessing availability trends and alerts
Gain business agility: Gain business agility:• Establishing business requirements and technology strategies• Readying sites to support the system that you want to implement• Integrating technical requirements and business goals into a detailed design and demonstrating• that the network is functioning as specified• that the network is functioning as specified• Expertly installing, configuring, and integrating system components• Continually enhancing performance
Accelerate access to network applications and services:• Assessing and improving operational preparedness to support current and planned network technologies• Assessing and improving operational preparedness to support current and planned network technologies
and services • Improving service-delivery efficiency and effectiveness by increasing availability, resource capacity, and
performance • Improving the availability, reliability, and stability of the network and the applications running on it
Managing and resolving problems affecting your system and keeping software applications current
Chapter #28© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
• Managing and resolving problems affecting your system and keeping software applications current
Planning a Network Implementation
Implementation Components:• Description of the stepp p• Reference to design documents• Detailed implementation guidelines• Detailed roll back guidelines in case of failure• Detailed roll-back guidelines in case of failure• Estimated time needed for implementation
Summary Implementation Plan – overview of y pimplementation plan Detailed Implementation Plan – describes exact steps
necessary to complete the implementation phase includingnecessary to complete the implementation phase, including steps to verify and check the work of the network engineers implementing the plan
Chapter #29© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Chapter 1 Summary
Evolutionary changes are occurring within the campus network. Evolution requires careful planning and deployments based
on hierarchical designs. As the network evolves, new capabilities are added, usuallyAs the network evolves, new capabilities are added, usually
driven by application data flows. Implementing the increasingly complex set of business-
driven capabilities and services in the campus architecturedriven capabilities and services in the campus architecture is challenging if done in a piecemeal fashion. Any successful architecture must be based on a foundation
f lid d i th d i i l Th d ti fof solid design theory and principles. The adoption of an integrated approach based on solid systems design principles is a key to success.
Chapter #30© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Chapter 1 Labs
Lab 1-1 Clearing a Switch Lab 1-2 Clearing a Switch Connected to a Larger Network
Chapter #31© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Resources
www.cisco.com/en/US/products
Chapter #32© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
Chapter #33© 2007 – 2010, Cisco Systems, Inc. All rights reserved. Cisco Public
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