Chapter 1 1.1 LAN Design - PowerPoint Presentation

Slide1

Chapter 1

1.1 LAN Design

1.2 The Switched EnvironmentSlide2

Chapter 1: Objectives

Describe the convergence of data, voice, and video in the context of switched networks.

Describe a switched network in a small-to-medium-sized business.

Explain the process of frame forwarding in a switched network.

Compare a collision domain to a broadcast domain.Slide3

Legacy Telephone EquipmentSlide4

Separate Networks

Voice Network

Video Network

Data NetworkSlide5

Converged Networks

Convergence combines voice and video communications on a data network.

The impact of moving a conventional company architecture to a completely converged network creates a shared infrastructure resulting in a single network to manage.

A primary benefit of a converged network is that there is just one physical network to install and manage.

Results in substantial savings over the installation and management of separate voice, video, and data networks. Slide6

Converged Networks

To support collaboration, business networks employ converged solutions using voice systems, IP phones, voice gateways, video support, and video

conferencing.Slide7

Converged Networks

The

convergence of services onto the

data network

has resulted in an evolution in networks.It’s gone from a traditional data transport role, to a super-highway for data, voice, and video communication.

Therefore, the converged network must be properly designed and implemented to allow the reliable handling of the various types of information that it must carry. A structured design is required to allow management of this complex environment.Slide8

Borderless Networks

The

Cisco Borderless

Network provides an

architectural approach that embeds intelligence, simplifies operations, and is scalable to meet demands of the converged network.It can

connect anyone, anywhere, anytime, on any device - securely, reliably, and seamlessly. It provides the framework to unify wired and wireless access across many different device types. Slide9

Borderless Networks

Borderless networks are built using following

principles

:

These

are not independent principles, therefore, understanding how each principle fits in the context of the others is critical.

Network Design Principles

Explanation

Hierarchy

Facilitates understanding the role of each device at every tier, simplifies deployment, operation, and management, and reduces fault domains at every tier.

Modularity

Allows seamless network expansion and integrated service enablement on an on-demand basis.

Resiliency

Satisfies user expectations by keeping the network operational.

Flexibility

Allows intelligent traffic load sharing by using all network resources.Slide10

Borderless Networks

Designing

a borderless switched network in a hierarchical fashion

allows

network designers to overlay security, mobility, and unified communication features. There are two

time-tested and proven hierarchical design frameworks for campus networks.

Three-tier hierarchical model

Two-tier hierarchical modelSlide11

Borderless Networks

Introducing

modularity into the campus hierarchical design further ensures that the campus network remains resilient and flexible enough to provide critical network services.

Modularity

also helps to allow for growth and changes that occur over time.Slide12

Role of Switched Networks

Switched networks incorporate the following features:

Layer 3 functionality

Quality of service

IP telephonySecurity

Wireless networkingMobilityMeeting the requirements of next generation networks:SecureReliable and always availableSupport converged network traffic such as data, voice, video, security systems, and moreSlide13

Switch Considerations

There are various types of

enterprise switches and the following are features to consider when selecting them.

Consideration

Explanation

Cost

Cost of a switch depends on the number and speed of the interfaces, supported features, and expansion capability.

Port Density

Network switches must support the appropriate number of devices on the network.

Power

Some

switches support

Power over Ethernet (PoE) .

Some chassis-based switches support redundant power supplies.

Reliability

Switch should provide continuous access to the network.

Port Speed

Speed of the network connection.

Frame Buffers

Switch should be able to store frames for congested ports.

Scalability

Switch should provide the opportunity for growthSlide14

Switch Form Factor

Switch form factor refers to the type of switch and the thickness of it when mounted in a rack.

The thickness of the switch is expressed in number of rack units (e.g., 1U, 2U, ….).

Network designers

must choose between:

Fixed configuration switchModular configuration switchStackable or non-stackable switchSlide15

Fixed Configuration Switches

Fixed configuration switches

are basically “what you see is what you get” and they do not support features

or options beyond those that originally came with

it.

1USlide16

Modular Switches

Modular configuration switches

are more flexible and typically

come with different sized chassis

supporting various modular line cards that fit into the switch chassis.Slide17

Stackable Switches

These switches

can be interconnected using a special

cable.

They can be daisy-chained and effectively managed as one large switch using the Cisco StackWise technology.Slide18

L2 and L3 Switches

Switches are also identified as either:

Layer 2

Layer 3 (or multilayer switch)

L3 switches are typically deployed in the core and distribution layers of an organization's switched network.

They can build a routing table, support a few routing protocols, and forward IP packets at a rate close to that of Layer 2 forwarding. Multilayer switches often support specialized hardware, such as application-specific integrated circuits (ASICs). Slide19

L2 and L3 Switches

There

is a trend in networking toward a pure Layer 3 switched environment.

Access layer switches are usually L2 switches.

Most switches now support routing and it is likely that soon all switches will incorporate a route processor because the cost of doing so is decreasing relative to other constraints.

Eventually the term multilayer switch will be redundant.Slide20

Enterprise Level Switches

Characteristics of enterprise level switches include:

Port Density

High Forwarding Rates

Support for Link AggregationSupports higher throughput by combining multiple switch portsSlide21

Port Density

This is the number of ports available on a single switch.

Remember, some of these ports will be used to interconnect the switch to the rest of the network!Slide22

Forwarding Rate

Defines the processing capabilities of a switch by rating how much data the switch can process per second.

Switch product lines are classified by forwarding rates.

Entry-layer switches have lower forwarding rates than enterprise-layer switches. Slide23

Forwarding Rate

Wire speed

describes the theoretical maximum data transmission rate that each port on the switch is capable of attaining

Because access layer switches are physically limited by their uplinks to the distribution layer they don’t need to operate at full wire speed.

Therefore use:

Less expensive, lower performing switches at the access layerMore expensive, higher performing switches at the distribution and core layers where forwarding rate makes a bigger impact.Slide24

Link Aggregation

Are there enough ports on a switch to aggregate to support the required bandwidth?

A 24-port switch, with each port capable of running at gigabit speed could generate up to 24

Gb

/s of network traffic.What if this switch is connected to the network with one 1

Gbps link?Bandwidth contention would occur.Each port would get 1/24th of the available wire speed.Data would be forwarded more slowly.Slide25

Link Aggregation

Link aggregation helps reduce traffic bottlenecks by allowing up to 8 switch ports to be bound together for data communications.

Link aggregation supports higher throughput by combining multiple switch ports.Slide26

Power over Ethernet (PoE)

Allows the switch to deliver power to a device over the existing Ethernet cabling.

Can provide power to IP phones and wireless access points.Slide27

PoE

Pass-Through Switches

Some switches such as the Cisco

Catalyst 2960-C and 3560-C Series compact switches support PoE pass-through.

PoE pass-through allows a network administrator to power PoE devices connected to the switch, as well as the switch itself, by drawing power from certain upstream switches. Slide28

Enterprise Switches

There is no one switch to “switch them all”.

An enterprise would require the services of many different switches based on its function as a core, distribution, and access layer.

Cisco SwitchesSlide29

Access Layer Switches

Cisco Catalyst 2960 Series

Cisco Catalyst 2960 and 2960-C Series Compact Switches Slide30

Catalyst 2960

Entry-layer enterprise, medium-sized, and branch office network switch

Forwarding rates from 16

Gb

/s to 32 Gb/sMultilayered switching

QoS features to support IP communicationsAccess control lists (ACLs)Fast Ethernet and Gigabit Ethernet connectivityUp to 48 10/100 ports or 10/100/1000 ports with additional dual purpose gigabit uplinksNo PoE supportCLI, Web management, Network Assistant, console, AUX access Slide31

Catalyst 2960Slide32

Distribution and Access Layer Switches

Cisco Catalyst 3560-X Series 

Cisco Catalyst 3750-X Series

Cisco Catalyst 4500E Series Slide33

Catalyst 3560

Enterprise-class switch supports PoE,

QoS

, and advanced security features (ACLs)

Small enterprise LAN access or branch-office converged network environments.Different fixed configurations:Fast Ethernet and Gigabit Ethernet connectivity

Up to 48 10/100/1000 ports, plus four small form-factor pluggable (SFP) portsOptional 10 Gigabit Ethernet connectivity in the Catalyst 3560-E modelsOptional Integrated PoE (Cisco pre-standard and IEEE 802.3af); up to 24 ports with 15.4 watts or 48 ports with 7.3 wattsSlide34

Catalyst 3560Slide35

Catalyst 3750

Access layer switches in midsize organizations and enterprise branch offices

Forwarding rates from 32

Gb

/s to 128 Gb/s

Supports Cisco StackWise technologyStackWise technology allows up to 9 switches to be interconnected via the use of a fully redundant backplane. Different stackable fixed configurations:Fast Ethernet and Gigabit Ethernet connectivityUp to 48 10/100/1000 ports, plus four SFP portsOptional 10 Gigabit Ethernet connectivity in the Catalyst 3750-E models

Optional Integrated PoE (Cisco pre-standard and IEEE 802.3af); up to 24 ports with 15.4 watts or 48 ports with 7.3 wattsSlide36

Catalyst 3750Slide37

Catalyst 4500

Distribution Layer switch that provides multilayer switching for enterprises, small- to medium-sized businesses, and service providers.

Forwarding rates up to 136

Gb

/sDifferent modular configurations:

Modular 3, 6, 7, and 10 slot chassis offering different layers of scalabilityHigh port density: up to 384 Fast Ethernet or Gigabit Ethernet ports available in copper or fiber with 10 Gigabit uplinksPoE (Cisco pre-standard and IEEE 802.3af)Dual, hot-swappable internal AC or DC power suppliesAdvanced hardware-assisted IP routing capabilitiesSlide38

Catalyst 4500Slide39

Core and Distribution Layer Switches

Cisco Catalyst 6500 Series

Cisco Catalyst 4500E Series

Cisco Catalyst 4500-X Series

Cisco Catalyst 3750-X Series Slide40

Catalyst 6500

Optimized for secure, converged voice, video, and data networks.

Can manage traffic at the distribution and core layers.

Highest performing Cisco switch

Supports forwarding rates up to 720

Gb/s. Very large network environments found in enterprises, medium-sized businesses, and service providers.Slide41

Core Layer: Catalyst 6500Slide42

Catalyst 6500

Different modular configurations:

Modular 3, 4, 6, 9, and 13 slot chassis

LAN/WAN service modules

PoE up to 420 IEEE 802.3af Class 3 (15.4W) PoE devicesUp to 1152 10/100 ports, 577 10/100/1000 ports, 410 SFP Gigabit Ethernet ports, or 64 10 Gigabit Ethernet ports

Dual, hot-swappable internal AC or DC power suppliesAdvanced hardware-assisted IP routing capabilitiesSlide43

Switching as a General Concept

The fundamental concept of switching refers to a device making a decision based on two criteria:

Ingress port

Destination address

A LAN switch maintains a MAC Address Table that it uses to determine how to forward traffic through the switchSlide44

Dynamically Populating a MAC Address Table

As the switch learns the relationship of ports to devices, it builds a table called a MAC address, or content addressable memory (CAM) table.Slide45

Switch Forwarding Methods

Application-specific-integrated circuits (ASICs) reduce the packet-handling time, and allow the device to handle an increased number of ports without degrading performance.

Two Methods of forwarding frames:

Store-and-Forward

-  makes a forwarding decision on a frame after it has received the entire frame and checked the frame for errors.

Cut-Through -  begins the forwarding process after the destination MAC address of an incoming frame and the egress port has been determined.NOTE:Cisco switches now all use Store and ForwardSlide46

Selective Forwarding

Cut-Through

Lowest Latency

No error checking

Fragment

Free

Low Latency

Checks for collisions

(Filters most errors)

Store

-

and

-

Forward

Highest Latency

All errors filtered

Lowest Latency Highest Latency

Less Error Checking More Error CheckingSlide47

Collision Domains

Each port on the switch represents a new segment.

Each new segment is a collision domain.Slide48

Broadcast Domains

Switches do not filter broadcast frames therefore a collection of interconnected switches forms a single broadcast domain. 

Routers are used to segment both collision and broadcast domainsSlide49

Alleviating Network Congestion

Characteristics of switches that contribute to alleviating network congestion:

Characteristics

Explanation

High port density

Large enterprise switches may support many hundreds of ports.

Large frame buffers

The ability to store many received frames.

Port speed

Depending on the cost of a switch, it may be possible to support a mixture of speeds.

Ports of 100 Mb/s, and 1 or 10 Gb/s are common (100 Gb/s is also possible).

Fast internal switching

Having fast internal forwarding capabilities allows high performance.

Low per-port cost

Switches provide high-port density at a lower cost and can accommodate network designs featuring fewer users per segment, therefore, increasing the average available bandwidth per user.Slide50

Chapter 1: Summary

The trend in networks is towards convergence using a single set of wires and devices to handle voice, video, and data transmission.

Network resources must now be seamlessly available anytime and anywhere.

The Cisco Borderless Network architecture enables different elements to work together and allow users access to resources from any place at any time.

The traditional three-layer hierarchical design model divides the network into core, distribution, and access layers. It provides modularity, resiliency, and flexibility.

In some networks the functionality of the core layer and the distribution layer are often collapsed together.It is important to deploy the appropriate types of switches based on network requirements.Slide51

Chapter 1: Summary (cont.)

The network designer must choose between a fixed or modular configuration, and stackable or non-stackable type of switch.

A network administrator may choose to implement a multilayer switch.

Multilayer switches are able to build a routing table, support a few routing protocols, and forward IP packets at a rate close to that of Layer 2 forwarding.

Switches use either store-and-forward or cut-through switching.

Every port on a switch forms a separate collision domain allowing for extremely high-speed full-duplex communication.Slide52