2 Communicating over the Network

2.0 Chapter Introduction

2.0.1 Chapter Introduction

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More and more, it is networks that connect us. People communicate online from everywhere. Efficient, dependable technology enables networks to be available whenever and wherever we need them. As our human network continues to expand, the platform that connects and supports it must also grow.

Rather than developing unique and separate systems for the delivery of each new service, the network industry as a whole has developed the means to both analyze the existing platform and enhance it incrementally. This ensures that existing communications are maintained while new services are introduced that are both cost effective and technologically sound.

In this course, we focus on these aspects of the information network:

• Devices that make up the network
• Media that connect the devices
• Messages that are carried across the network
• Rules and processes that govern network communications
• Tools and commands for constructing and maintaining networks

Central to the study of networks is the use of generally-accepted models that describe network functions. These models provide a framework for understanding current networks and for facilitating the development of new technologies to support future communications needs.

Within this course, we use these models, as well as tools designed to analyze and simulate network functionality. Two of the tools that will enable you to build and interact with simulated networks are Packet Tracer 4.1 software and Wireshark network protocol analyzer.

This chapter prepares you to:

• Describe the structure of a network, including the devices and media that are necessary for successful communications.
• Explain the function of protocols in network communications.
• Explain the advantages of using a layered model to describe network functionality.
• Describe the role of each layer in two recognized network models: The TCP/IP model and the OSI model.
• Describe the importance of addressing and naming schemes in network communications.

2.0.1 - Chapter Introduction
The diagram depicts a person with a PDA sending a message to three other people simultaneously.

This course focuses on the platform that enables us to communicate quickly, reliably, safely, and economically.

2.1 The Platform for Communications

2.1.1 The Elements of Communication

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Communication begins with a message, or information, that must be sent from one individual or device to another. People exchange ideas using many different communication methods. All of these methods have three elements in common. The first of these elements is the message source, or sender. Message sources are people, or electronic devices, that need to send a message to other individuals or devices. The second element of communication is the destination, or receiver, of the message. The destination receives the message and interprets it. A third element, called a channel, consists of the media that provides the pathway over which the message can travel from source to destination.

Consider, for example, the desire to communicate using words, pictures, and sounds. Each of these messages can be sent across a data or information network by first converting them into binary digits, or bits. These bits are then encoded into a signal that can be transmitted over the appropriate medium. In computer networks, the media is usually a type of cable, or a wireless transmission.

The term network in this course will refer to data or information networks capable of carrying many different types of communications, including traditional computer data, interactive voice, video, and entertainment products.

2.1.1 - The Elements of Communication
The animation depicts two examples of encoding: one by two humans and one by two computers. In each example, communication occurs first by the source encoding a message and the destination decoding a message. In this case, the source encodes a description of a sunset. The destination then decodes the message, which results in receiving the description of the sunset as sent by the source. The communication process is described in text boxes moving from left to right as follows: Message Source (Message) - Encoder (signal) - Transmitter - Transmission Medium (Channel) - Receiver (Signal) - Decoder (message) - Message Destination.

2.1.2 Communicating the Messages

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In theory, a single communication, such as a music video or an e-mail message, could be sent across a network from a source to a destination as one massive continuous stream of bits. If messages were actually transmitted in this manner, it would mean that no other device would be able to send or receive messages on the same network while this data transfer was in progress. These large streams of data would result in significant delays. Further, if a link in the interconnected network infrastructure failed during the transmission, the complete message would be lost and have to be retransmitted in full.

A better approach is to divide the data into smaller, more manageable pieces to send over the network. This division of the data stream into smaller pieces is called segmentation. Segmenting messages has two primary benefits.

First, by sending smaller individual pieces from source to destination, many different conversations can be interleaved on the network. The process used to interleave the pieces of separate conversations together on the network is called multiplexing.

Second, segmentation can increase the reliability of network communications. The separate pieces of each message need not travel the same pathway across the network from source to destination. If a particular path becomes congested with data traffic or fails, individual pieces of the message can still be directed to the destination using alternate pathways. If part of the message fails to make it to the destination, only the missing parts need to be retransmitted.

2.1.2 - Communicating the Messages
The animation depicts two people at computers sending messages simultaneously over a single communications link. The animation illustrates the concept of segmenting messages and combining them over a common link. Multiple communications are interleaved, giving each user a part of the bandwidth.
- Segmentation - Breaking communication into pieces.
- Multiplexing - Interleaving the pieces as they traverse the media.

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The downside to using segmentation and multiplexing to transmit messages across a network is the level of complexity that is added to the process. Imagine if you had to send a 100-page letter, but each envelope would only hold one page. The process of addressing, labeling, sending, receiving, and opening the entire hundred envelopes would be time-consuming for both the sender and the recipient.

In network communications, each segment of the message must go through a similar process to ensure that it gets to the correct destination and can be reassembled into the content of the original message.

Various types of devices throughout the network participate in ensuring that the pieces of the message arrive reliably at their destination.

2.1.2 - Communicating the Messages
The diagram depicts two users at desktop PC's sending a message to the same server over a common link. Multiple pieces of the message are labeled. Labeling helps order and assemble the pieces when they arrive at the destination.

2.1.3 Components of the Network

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The path that a message takes from source to destination can be as simple as a single cable connecting one computer to another or as complex as a network that literally spans the globe. This network infrastructure is the platform that supports our human network. It provides the stable and reliable channel over which our communications can occur.

Devices and media are the physical elements or hardware of the network. Hardware is often the visible components of the network platform such as a laptop, a PC, a switch, or the cabling used to connect the devices. Occasionally, some components may not be so visible. In the case of wireless media, messages are transmitted through the air using invisible radio frequency or infrared waves.

Services and processes are the communication programs, called software, that run on the networked devices. A network service provides information in response to a request. Services include many of the common network applications people use every day, like e-mail hosting services and web hosting services. Processes provide the functionality that directs and moves the messages through the network. Processes are less obvious to us but are critical to the operation of networks.

2.1.3 - Components of the Network
The diagram depicts two local networks connected by a group of four routers representing an internetwork. The primary network components are highlighted and grouped into categories: devices, media, and services.

Devices - Switches, routers, servers, end-user computers, IP phones.
Media - The cabling (and wireless) between networking devices.
Services - Software, processes, applications, protocols (rules).

2.1.4 End Devices and their Role on the Network

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The network devices that people are most familiar with are called end devices. These devices form the interface between the human network and the underlying communication network. Some examples of end devices are:

• Computers (work stations, laptops, file servers, web servers)
• Network printers
• VoIP phones
• Security cameras
• Mobile handheld devices (such as wireless barcode scanners, PDAs)

In the context of a network, end devices are referred to as hosts. A host device is either the source or destination of a message transmitted over the network. In order to distinguish one host from another, each host on a network is identified by an address. When a host initiates communication, it uses the address of the destination host to specify where the message should be sent.

In modern networks, a host can act as a client, a server, or both. Software installed on the host determines which role it plays on the network.

Servers are hosts that have software installed that enables them to provide information and services, like e-mail or web pages, to other hosts on the network.

Clients are hosts that have software installed that enables them to request and display the information obtained from the server.

2.1.4 - End Devices and Their Role on the Network
The animation depicts two local networks connected by a group of four routers representing an internetwork. Data originates with an end device, flows through the network, and arrives at another end device. Messages can take alternate routes through the internetwork.

2.1.5 Intermediary Devices and their Role on the Network

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In addition to the end devices that people are familiar with, networks rely on intermediary devices to provide connectivity and to work behind the scenes to ensure that data flows across the network. These devices connect the individual hosts to the network and can connect multiple individual networks to form an internetwork. Examples of intermediary network devices are:

• Network Access Devices (Hubs, switches, and wireless access points)
• Internetworking Devices (routers)
• Communication Servers and Modems
• Security Devices (firewalls)

The management of data as it flows through the network is also a role of the intermediary devices. These devices use the destination host address, in conjunction with information about the network interconnections, to determine the path that messages should take through the network. Processes running on the intermediary network devices perform these functions:

• Regenerate and retransmit data signals
• Maintain information about what pathways exist through the network and internetwork
• Notify other devices of errors and communication failures
• Direct data along alternate pathways when there is a link failure
• Classify and direct messages according to QoS priorities
• Permit or deny the flow of data, based on security settings

2.1.5 - Intermediary Devices and Their Role on the Network
The animation depicts a group of four routers representing an internetwork. Intermediary devices direct the path of the data, but do not generate or change the data content. As messages are sent, text around the routers is displayed as follows:
"This message is important, give it priority."
"This message is broken, resend it."
"This message will arrive faster if it goes this way."

2.1.6 Network Media

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Communication across a network is carried on a medium. The medium provides the channel over which the message travels from source to destination.

Modern networks primarily use three types of media to interconnect devices and to provide the pathway over which data can be transmitted. These media are:

• Metallic wires within cables
• Glass or plastic fibers (fiber optic cable)
• Wireless transmission

The signal encoding that must occur for the message to be transmitted is different for each media type. On metallic wires, the data is encoded into electrical impulses that match specific patterns. Fiber optic transmissions rely on pulses of light, within either infrared or visible light ranges. In wireless transmission, patterns of electromagnetic waves depict the various bit values.

Different types of network media have different features and benefits. Not all network media has the same characteristics and is appropriate for the same purpose. Criteria for choosing a network media are:

• The distance the media can successfully carry a signal.
• The environment in which the media is to be installed.
• The amount of data and the speed at which it must be transmitted.
• The cost of the media and installation

2.1.6 - Network Media
The diagram depicts multiple images showing examples of network media, including:
- Copper U TP cables and connectors
- Fiber optic cables and connectors
- Wireless routers, a wireless web cam, and wireless NIC

2.2 LANs, WANs, and Internetworks

2.2.1 Local Area Networks

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Networks infrastructures can vary greatly in terms of:

• The size of the area covered
• The number of users connected
• The number and types of services available

An individual network usually spans a single geographical area, providing services and applications to people within a common organizational structure, such as a single business, campus or region. This type of network is called a Local Area Network (LAN). A LAN is usually administered by a single organization. The administrative control that governs the security and access control policies are enforced on the network level.

2.2.1 - Local Area Networks
The diagram depicts two computers with users, a standalone PC, an IP phone, and a server all connected to a switch. A network serving a home, building, or campus is a local area network (LAN).

2.2.2 Wide Area Networks

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When a company or organization has locations that are separated by large geographical distances, it may be necessary to use a telecommunications service provider (TSP) to interconnect the LANs at the different locations. Telecommunications service providers operate large regional networks that can span long distances. Traditionally, TSPs transported voice and data communications on separate networks. Increasingly, these providers are offering converged information network services to their subscribers.

Individual organizations usually lease connections through a telecommunications service provider network. These networks that connect LANs in geographically separated locations are referred to as Wide Area Networks (WANs). Although the organization maintains all of the policies and administration of the LANs at both ends of the connection, the policies within the communications service provider network are controlled by the TSP.

WANs use specifically designed network devices to make the interconnections between LANs. Because of the importance of these devices to the network, configuring, installing and maintaining these devices are skills that are integral to the function of an organization's network.

LANs and WANs are very useful to individual organizations. They connect the users within the organization. They allow many forms of communication including exchange e-mails, corporate training, and other resource sharing.

2.2.2 - Wide Area Networks
The diagram depicts two LAN's interconnected using two routers and a WAN link. Each router is connected to its respective LAN switch, along with the PC's, servers, and IP phone in the LAN. LAN's separated by geographical distance are connected by a network known as a wide area network (WAN).

2.2.3 The Internet - A Network of Networks

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Although there are benefits to using a LAN or WAN, most of us need to communicate with a resource on another network, outside of our local organization.

Examples of this type of communication include:

• Sending an e-mail to a friend in another country
• Accessing news or products on a website
• Getting a file from a neighbor's computer
• Instant messaging with a relative in another city
• Following a favorite sporting team's performance on a cell phone

Internetwork

A global mesh of interconnected networks (internetworks) meets these human communication needs. Some of these interconnected networks are owned by large public and private organizations, such as government agencies or industrial enterprises, and are reserved for their exclusive use. The most well-known and widely used publicly-accessible internetwork is the Internet.

The Internet is created by the interconnection of networks belonging to Internet Service Providers (ISPs). These ISP networks connect to each other to provide access for millions of users all over the world. Ensuring effective communication across this diverse infrastructure requires the application of consistent and commonly recognized technologies and protocols as well as the cooperation of many network administration agencies.

Intranet

The term intranet is often used to refer to a private connection of LANs and WANs that belongs to an organization, and is designed to be accessible only by the organization's members, employees, or others with authorization.

Note: The following terms may be interchangeable: internetwork, data network, and network. A connection of two or more data networks forms an internetwork - a network of networks. It is also common to refer to an internetwork as a data network - or simply as a network - when considering communications at a high level. The usage of terms depends on the context at the time and terms may often be interchanged.

2.2.3 - The Internet - A Network of Networks
The diagram depicts ten LAN's interconnected using nine routers and multiple LAN/WAN communications links representing the Internet. LAN's and WAN's can be connected into an internetwork.

2.2.4 Network Representations

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When conveying complex information such as the network connectivity and operation of a large internetwork, it is helpful to use visual representations and graphics. Like any other language, the language of networking uses a common set of symbols to represent the different end devices, network devices and media. The ability to recognize the logical representations of the physical networking components is critical to being able to visualize the organization and operation of a network. Throughout this course and labs, you will learn both how these devices operate and how to perform basic configuration tasks on these devices.

In addition to these representations, specialized terminology is used when discussing how each of these devices and media connect to each other. Important terms to remember are:

Network Interface Card - A NIC, or LAN adapter, provides the physical connection to the network at the PC or other host device. The media connecting the PC to the networking device plugs directly into the NIC.

Physical Port - A connector or outlet on a networking device where the media is connected to a host or other networking device.

Interface - Specialized ports on an internetworking device that connect to individual networks. Because routers are used to interconnect networks, the ports on a router are referred to network interfaces.

2.2.4 -Network Representations
The diagram depicts multiple icons that represent common data network symbols. These include various types of computers (desktop, laptop, and server) and an IP phone. WAN and LAN wired and wireless media icons are shown. Generic symbols are shown for the LAN switch, LAN hub, router, wireless router, wireless access point, and firewall.

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In this activity, you will gain experience with data network symbols by creating a simple logical topology.

Click the Packet Tracer icon for more details.

2.2.4 -Network Representations
Link to Packet Tracer Activity: Network Representations

In this activity, you gain experience with data network symbols by creating a simple logical topology.

2.2.5 Activity - Using NeoTrace™ to View Internetworks

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In this activity, you will observe the flow of information across the Internet. This activity should be performed on a computer that has Internet access and access to a command line. You will use the Windows embedded tracert utility and then the more enhanced NeoTrace program. This lab also assumes the installation of NeoTrace.

Click the Lab Icon for more details.

2.2.5 - Activity - Using NeoTrace to View Internetworks
Link to Hands-on Lab: Using NeoTrace to View Internetworks

In this activity, you observe the flow of information across the Internet. This activity should be performed on a computer that has Internet access and access to a command line. You use the Windows-embedded trace rt utility and then the more enhanced NeoTrace program. This lab assumes that you have NeoTrace installed.

2.3 Protocols

2.3.1 Rules that Govern Communications

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All communication, whether face-to-face or over a network, is governed by predetermined rules called protocols. These protocols are specific to the characteristics of the conversation. In our day-to-day personal communication, the rules we use to communicate over one medium, like a telephone call, are not necessarily the same as the protocols for using another medium, such as sending a letter.

Think of how many different rules or protocols govern all the different methods of communication that exist in the world today.

Successful communication between hosts on a network requires the interaction of many different protocols. A group of inter-related protocols that are necessary to perform a communication function is called a protocol suite. These protocols are implemented in software and hardware that is loaded on each host and network device.

One of the best ways to visualize how all of the protocols interact on a particular host is to view it as a stack. A protocol stack shows how the individual protocols within the suite are implemented on the host. The protocols are viewed as a layered hierarchy, with each higher level service depending on the functionality defined by the protocols shown in the lower levels. The lower layers of the stack are concerned with moving data over the network and providing services to the upper layers, which are focused on the content of the message being sent and the user interface.

Using layers to describe face-to-face communication

For example, consider two people communicating face-to-face. As the figure shows, we can use three layers to describe this activity. At the bottom layer, the Physical layer, we have two people, each with a voice that can utter words aloud. At the second layer, the Rules layer, we have an agreement to speak in a common language. At the top layer, the Content layer, we have the words actually spoken-the content of the communication.

Were we to witness this conversation, we would not actually see "layers" floating in space. It is important to understand that the use of layers is a model and, as such, it provides a way to conveniently break a complex task into parts and describe how they work.

2.3.1 - Rules that Govern Communications
The diagram depicts protocol suites, which are sets of rules that work together to help solve a problem. Protocol suites controls the Content Layer, Rules Layer, and Physical Layer.

- Content Layer: Example: Where is the cafe?
- Rules Layer: Conversation Protocol Suite
1. Use a Common Language
2. Wait Your Turn
3. Signal When Finished
- Physical Layer: Example: Shows two people.

2.3.2 Network Protocols

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At the human level, some communication rules are formal and others are simply understood, or implicit, based on custom and practice. For devices to successfully communicate, a network protocol suite must describe precise requirements and interactions.

Networking protocol suites describe processes such as:

• The format or structure of the message
• The method by which networking devices share information about pathways with other networks
• How and when error and system messages are passed between devices
• The setup and termination of data transfer sessions

Individual protocols in a protocol suite may be vendor-specific and proprietary. Proprietary, in this context, means that one company or vendor controls the definition of the protocol and how it functions. Some proprietary protocols can be used by different organizations with permission from the owner. Others can only be implemented on equipment manufactured by the proprietary vendor.

2.3.2 - Network Protocols
The diagram depicts the role of protocols and the concepts of format, process, error messages, and termination. An end-user PC is connected to a router that is connected to two other routers. One of the other routers is connected to a server.

Format: The format or structure of the communication pieces.
Router 1 speech bubble says: "Let us all agree that pieces will be 10 letters long." The user PC and router 2 say: "Okay."
In any communication process, there are rules.

Process: The process by which networking devices share information about pathways to other networks.
Router 2 speech bubble says: "Let us all agree that if one of our pathways is down, we will notify all connected devices."
Router 1 says: "Path A is down." Routers 2, 3, and 4 say: "Okay."

Error Messages: How and when error and system messages are passed between devices.
Router 2 speech bubble says: "Let us all agree that error messages will have a unique ID number."
Router 1 says: "Error 1002: Path B is slow."
Router 2 says: "Error 1001: Path A is down."

Termination: The setting up and termination of data transfer sessions.
Router 2 speech bubble says: "Let us all agree that sessions will end after 60 seconds of inactivity."
Router 2 then says: "It has been 60 seconds since the last piece arrived. Closing this session." The other router says: "Okay."

2.3.3 Protocol Suites and Industry Standards

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Often, many of the protocols that comprise a protocol suite reference other widely utilized protocols or industry standards. A standard is a process or protocol that has been endorsed by the networking industry and ratified by a standards organization, such as the Institute of Electrical and Electronics Engineers (IEEE) or the Internet Engineering Task Force (IETF).

The use of standards in developing and implementing protocols ensures that products from different manufacturers can work together for efficient communications. If a protocol is not rigidly observed by a particular manufacturer, their equipment or software may not be able to successfully communicate with products made by other manufacturers.

In data communications, for example, if one end of a conversation is using a protocol to govern one-way communication and the other end is assuming a protocol describing two-way communication, in all probability, no information will be exchanged.

2.3.3 - Protocol Suites and Industry Standards
The diagram depicts the three layers controlled by protocols suites: the Content Layer, Rules Layer, and the Physical Layer. It shows how a standard is used to ensure ensure consistency dare protocols and agreements that are widely used and accepted. The diagram is similar to diagram 2.3.1.1.
- Content Layer: Where is the cafe?
- Rules Layer: Conversation Protocol Suite
1. Use a common language
2. Wait your turn
3. Signal when finished
- Standard - Wait 2 full seconds to signal transmission has stopped
- Physical Layer: Shows two people involved in communication

2.3.4 The Interaction of Protocols

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An example of the use of a protocol suite in network communications is the interaction between a web server and a web browser. This interaction uses a number of protocols and standards in the process of exchanging information between them. The different protocols work together to ensure that the messages are received and understood by both parties. Examples of these protocols are:

Application Protocol:

Hypertext Transfer Protocol (HTTP) is a common protocol that governs the way that a web server and a web client interact. HTTP defines the content and formatting of the requests and responses exchanged between the client and server. Both the client and the web server software implement HTTP as part of the application. The HTTP protocol relies on other protocols to govern how the messages are transported between client and server

Transport Protocol:

Transmission Control Protocol (TCP) is the transport protocol that manages the individual conversations between web servers and web clients. TCP divides the HTTP messages into smaller pieces, called segments, to be sent to the destination client. It is also responsible for controlling the size and rate at which messages are exchanged between the server and the client.

Internetwork Protocol:

The most common internetwork protocol is Internet Protocol (IP). IP is responsible for taking the formatted segments from TCP, encapsulating them into packets, assigning the appropriate addresses, and selecting the best path to the destination host.

Network Access Protocols:

Network access protocols describe two primary functions, data link management and the physical transmission of data on the media. Data-link management protocols take the packets from IP and format them to be transmitted over the media. The standards and protocols for the physical media govern how the signals are sent over the media and how they are interpreted by the receiving clients. Transceivers on the network interface cards implement the appropriate standards for the media that is being used.

2.3.4 - The Interaction of Protocols
The diagram depicts a protocol stack and the interaction between key protocols used by a Web server to provide Web pages to clients. A Web server is shown with a protocol stack expanded next to it that consists of (from the bottom up): Ethernet protocol, Internet Protocol (IP),
Transmission Control Protocol (TCP), and Hypertext Transfer Protocol (HTTP).

2.3.5 Technology Independent Protocols

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Networking protocols describe the functions that occur during network communications. In the face-to-face conversation example, a protocol for communicating might state that in order to signal that the conversation is complete, the sender must remain silent for two full seconds. However, this protocol does not specify how the sender is to remain silent for the two seconds.

Protocols generally do not describe how to accomplish a particular function. By describing only what functions are required of a particular communication rule but not how they are to be carried out, the implementation of a particular protocol can be technology-independent.

Looking at the web server example, HTTP does not specify what programming language is used to create the browser, which web server software should be used to serve the web pages, what operating system the software runs on, or the hardware requirements necessary to display the browser. It also does not describe how the server should detect errors, although it does describe what the server should do if an error occurs.

This means that a computer - and other devices, like mobile phones or PDAs - can access a web page stored on any type of web server that uses any form of operating system from anywhere on the Internet.

2.3.5 - Technology Independent Protocols
The diagram depicts several different types of end-user devices (computers, cell phone, IP phone, and PDA) connected to a cloud labeled "Network" that uses both wired and wireless media. The caption text states: "Many diverse types of devices can communicate using the same sets of protocols. This is because protocols specify network functionality, not the underlying technology to support this functionality."

2.4 Using Layered Models

2.4.1 The Benefits of Using a Layered Model

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To visualize the interaction between various protocols, it is common to use a layered model. A layered model depicts the operation of the protocols occurring within each layer, as well as the interaction with the layers above and below it.

There are benefits to using a layered model to describe network protocols and operations. Using a layered model:

• Assists in protocol design, because protocols that operate at a specific layer have defined information that they act upon and a defined interface to the layers above and below.
• Fosters competition because products from different vendors can work together.
• Prevents technology or capability changes in one layer from affecting other layers above and below.
• Provides a common language to describe networking functions and capabilities.

2.4.1 - The Benefits of Using a Layered Model
The animation depicts two local networks connected to a group of four routers in a full mesh. These four interconnected routers make up the Internetwork. Each local network has a switch that is connected to one of the four routers. Also connected to the switch are end-user computers, an IP phone, and a server. One router has a text box that says: Rule 1 Rule 2 Rule 3.
Caption text: "Using a layered model helps in the design of complex, multi-use, multi-vendor networks. Individual parts of the system can be designed independently, but still work together seamlessly."

2.4.2 Protocol and Reference Models

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There are two basic types of networking models: protocol models and reference models.

A protocol model provides a model that closely matches the structure of a particular protocol suite. The hierarchical set of related protocols in a suite typically represents all the functionality required to interface the human network with the data network. The TCP/IP model is a protocol model because it describes the functions that occur at each layer of protocols within the TCP/IP suite.

A reference model provides a common reference for maintaining consistency within all types of network protocols and services. A reference model is not intended to be an implementation specification or to provide a sufficient level of detail to define precisely the services of the network architecture. The primary purpose of a reference model is to aid in clearer understanding of the functions and process involved.

The Open Systems Interconnection (OSI) model is the most widely known internetwork reference model. It is used for data network design, operation specifications, and troubleshooting.

Although the TCP/IP and OSI models are the primary models used when discussing network functionality, designers of network protocols, services, or devices can create their own models to represent their products. Ultimately, designers are required to communicate to the industry by relating their product or service to either the OSI model or the TCP/IP model, or to both.

2.4.2 - Protocol and Reference Models
The upper portion of the diagram depicts two local networks connected to a group of four routers in a full mesh. The text states: "Network diagrams depict actual devices in their relationships."

The lower portion of the diagram depicts the O S I reference model on the left and the TCP/IP protocol model on the right. The text states: "A networking model is only a representation of network operation. The model is not the actual network." The layers in the O S I model (from top to bottom) are: Application, Presentation, Session, Transport, Network, Data Link, and Physical. The protocol layers in the TCP/IP model (from top to bottom) are: Application, Transport, Internet, and Network Access.

2.4.3 The TCP/IP Model

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The first layered protocol model for internetwork communications was created in the early 1970s and is referred to as the Internet model. It defines four categories of functions that must occur for communications to be successful. The architecture of the TCP/IP protocol suite follows the structure of this model. Because of this, the Internet model is commonly referred to as the TCP/IP model.

Most protocol models describe a vendor-specific protocol stack. However, since the TCP/IP model is an open standard, one company does not control the definition of the model. The definitions of the standard and the TCP/IP protocols are discussed in a public forum and defined in a publicly-available set of documents. These documents are called Requests for Comments (RFCs). They contain both the formal specification of data communications protocols and resources that describe the use of the protocols.

The RFCs also contain technical and organizational documents about the Internet, including the technical specifications and policy documents produced by the Internet Engineering Task Force (IETF).

2.4.3 - The TCP/IP Model
The diagram depicts the functions of the TCP/IP protocol model layers in greater detail.
Application - Represents data to the user, plus encoding and dialog control.
Transport - Supports communication between diverse devices across diverse networks.
Internet - Determines the best path through the network.
Network Access - Controls the hardware devices and media that make up the network.

2.4.4 The Communication Process

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The TCP/IP model describes the functionality of the protocols that make up the TCP/IP protocol suite. These protocols, which are implemented on both the sending and receiving hosts, interact to provide end-to-end delivery of applications over a network.

A complete communication process includes these steps:

1. Creation of data at the Application layer of the originating source end device

2. Segmentation and encapsulation of data as it passes down the protocol stack in the source end device

3. Generation of the data onto the media at the Network Access layer of the stack

4. Transportation of the data through the internetwork, which consists of media and any intermediary devices

5. Reception of the data at the Network Access layer of the destination end device

6. Decapsulation and reassembly of the data as it passes up the stack in the destination device

7. Passing this data to the destination application at the Application layer of the destination end device

2.4.4 - The Communication Process
Title: "Untouched Message Travels through a Network"
The animation depicts the process of sending a message from a user with a handheld PDA over the network to another user at a desktop PC. The PDA protocol stack is connected to router 1. The desktop PC protocol stack is connected to router 2, and the two routers are connected. The envelope or packet travels from the PDA, down through the layers of its TCP/IP stack (Application to Transport to Internet to Network Access) to router 1. It then travels across the communication link to router 2, and up through the layers of the desktop PC protocol stack to the PC (Network Access to Internet to Transport to Application).

2.4.5 Protocol Data Units and Encapsulation

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As application data is passed down the protocol stack on its way to be transmitted across the network media, various protocols add information to it at each level. This is commonly known as the encapsulation process.

The form that a piece of data takes at any layer is called a Protocol Data Unit (PDU). During encapsulation, each succeeding layer encapsulates the PDU that it receives from the layer above in accordance with the protocol being used. At each stage of the process, a PDU has a different name to reflect its new appearance. Although there is no universal naming convention for PDUs, in this course, the PDUs are named according to the protocols of the TCP/IP suite.

• Data - The general term for the PDU used at the Application layer
• Segment - Transport Layer PDU
• Packet - Internetwork Layer PDU
• Frame - Network Access Layer PDU
• Bits - A PDU used when physically transmitting data over the medium

2.4.5 - Protocol Data Units and Encapsulation
The diagram depicts the use of Protocol Data Units (PDU's) and the encapsulation process when sending a message from a user. The user PC is connected to a router. The PDU terminology is given at each encapsulation step. The process starts when the user creates the email message, which is termed a Data PDU. As the data is passed down the protocol stack, a transport header is added, creating a Segment PDU. Next a network header is added, creating a Packet PDU. Then a frame header and trailer are added, creating a Frame PDU. Finally, the frame is transmitted on the medium as bits (zeros and ones).

PDU Summary (passing down the stack):
- Data - The general term for the PDU used at the Application Layer.
- Segment - Transport Layer PDU
- Packet - Internetwork Layer PDU
- Frame - Network Access Layer PDU
- Bits - PDU used when physically transmitting data over the medium.

2.4.6 The Sending and Receiving Process

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When sending messages on a network, the protocol stack on a host operates from top to bottom. In the web server example, we can use the TCP/IP model to illustrate the process of sending an HTML web page to a client.

The Application layer protocol, HTTP, begins the process by delivering the HTML formatted web page data to the Transport layer. There the application data is broken into TCP segments. Each TCP segment is given a label, called a header, containing information about which process running on the destination computer should receive the message. It also contains the information to enable the destination process to reassemble the data back to its original format.

The Transport layer encapsulates the web page HTML data within the segment and sends it to the Internet layer, where the IP protocol is implemented. Here the entire TCP segment is encapsulated within an IP packet, which adds another label, called the IP header. The IP header contains source and destination host IP addresses, as well as information necessary to deliver the packet to its corresponding destination process.

Next, the IP packet is sent to the Network Access layer Ethernet protocol where it is encapsulated within a frame header and trailer. Each frame header contains a source and destination physical address. The physical address uniquely identifies the devices on the local network. The trailer contains error checking information. Finally the bits are encoded onto the Ethernet media by the server NIC.

2.4.6 - The Sending and Receiving Process
The animation depicts the encapsulation process and protocol operation when sending a web page from a Web server to a Web client over an Ethernet network. The client requests a Web page, and the server sends the web page to the client. The Web page data is encapsulated with a TCP transport header, which creates the TCP Segment. Next, the TCP Segment is encapsulated in an IP header creating a packet. Then the Ethernet frame header and trailer encapsulate the IP packet, creating an Ethernet frame. Finally, the Ethernet frame is transmitted on the medium as bits (zeros and ones).

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This process is reversed at the receiving host. The data is decapsulated as it moves up the stack toward the end user application.

2.4.6 - The Sending and Receiving Process
The animation depicts the de-encapsulation process (the reverse of the encapsulation process) and protocol operation when receiving a Web page from a Web server over an Ethernet network. The client receives the web page as bits (zeros and ones). Then the Ethernet frame header and trailer are removed (de-encapsulated) from the IP packet. Next, the IP header is removed (de-encapsulated) from the TCP segment. Finally, the TCP header is removed (de-encapsulated) from the data (actual web page), which is passed up to the Web client application to be displayed on the user's screen.

2.4.7 The OSI Model

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Initially the OSI model was designed by the International Organization for Standardization (ISO) to provide a framework on which to build a suite of open systems protocols. The vision was that this set of protocols would be used to develop an international network that would not be dependent on proprietary systems.

Unfortunately, the speed at which the TCP/IP based Internet was adopted, and the rate at which it expanded, caused the OSI Protocol Suite development and acceptance to lag behind. Although few of the protocols developed using the OSI specifications are in widespread use today, the seven-layer OSI model has made major contributions to the development of other protocols and products for all types of new networks.

As a reference model, the OSI model provides an extensive list of functions and services that can occur at each layer. It also describes the interaction of each layer with the layers directly above and below it. Although the content of this course will be structured around the OSI Model the focus of discussion will be the protocols identified in the TCP/IP protocol stack.

Note that whereas the TCP/IP model layers are referred to only by name, the seven OSI model layers are more often referred to by number than by name.

2.4.7 - The O S I Model
The diagram depicts the seven layers of the O S I reference model and provides a brief description and function of each layer.

Layer 7. Application - The Application Layer provides the means for end-to-end connectivity between individuals using data networks.
Layer 6. Presentation - The Presentation Layer provides for common representation of the data transferred between Application Layer services.
Layer 5. Session - The Session Layer provides services to the Presentation Layer to organize its dialogue and to manage data exchange.
Layer 4. Transport - The Transport Layer defines services to segment, transfer, and reassemble the data for individual communications between the end devices.
Layer 3. Network - The Network Layer provides services to exchange the individual pieces of data over the network between identified end devices.
Layer 2. Data Link - The Data Link Layer protocols describe methods for exchanging data frames between devices over a common media.
Layer 1. Physical - The Physical Layer protocols describe the mechanical, electrical, functional, and procedural means to activate, maintain, and de-activate physical connections for bit transmission to and from a network device.

2.4.8 Comparing the OSI Model with the TCP/IP Model

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The protocols that make up the TCP/IP protocol suite can be described in terms of the OSI reference model. In the OSI model, the Network Access layer and the Application layer of the TCP/IP model are further divided to describe discreet functions that need to occur at these layers.

At the Network Access Layer, the TCP/IP protocol suite does not specify which protocols to use when transmitting over a physical medium; it only describes the handoff from the Internet Layer to the physical network protocols. The OSI Layers 1 and 2 discuss the necessary procedures to access the media and the physical means to send data over a network.

The key parallels between the two network models occur at the OSI model Layers 3 and 4. OSI Model Layer 3, the Network layer, almost universally is used to discuss and document the range of processes that occur in all data networks to address and route messages through an internetwork. The Internet Protocol (IP) is the TCP/IP suite protocol that includes the functionality described at Layer 3.

Layer 4, the Transport layer of the OSI model, is often used to describe general services or functions that manage individual conversations between source and destination hosts. These functions include acknowledgement, error recovery, and sequencing. At this layer, the TCP/IP protocols Transmission Control Protocol (TCP) and User Datagram Protocol (UDP) provide the necessary functionality.

The TCP/IP Application layer includes a number of protocols that provide specific functionality to a variety of end user applications. The OSI model Layers 5, 6 and 7 are used as references for application software developers and vendors to produce products that need to access networks for communications.

2.4.8 - Comparing the O S I Model with the TCP/IP Model
The diagram depicts the O S I and TCP/IP models. It compares the layers of the seven-layer O S I model to those of the four-layer TCP/IP model. The key parallels between the two models are in the Transport and Network Layers. The functions of O S I Layers 5, 6, and 7 are included in the TCP/IP Application Layer. O S I Layer 4 is comparable to the TCP/IP Transport Layer. O S I Layer 3 is comparable to the TCP/IP Internet Layer. The functions of O S I Layers 1 and 2 are included in the TCP/IP Network Access Layer.

O S I Layer 7. Application relates to TCP/IP Layer 4 Application.
O S I Layer 6. Presentation relates to TCP/IP Layer 4 Application.
O S I Layer 5. Session relates to TCP/IP Layer 4 Application.
O S I Layer 4. Transport relates to TCP/IP Layer 3 Transport.
O S I Layer 3. Network relates to TCP/IP Layer 2 Internet.
O S I Layer 2. Data Link relates to TCP/IP Layer 1 Network Access.
O S I Layer 1. Physical relates to TCP/IP Layer 1 Network Access.

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In this activity, you will see how Packet Tracer uses the OSI Model as a reference to display the encapsulation details of a variety of the TCP/IP protocols.

Click the Packet Tracer icon for more details.

2.4.8 - Comparing the O S I Model with the TCP/IP Model
Link to Packet Tracer Activity: Use of the TCP/IP Protocols and the O S I Model in Packet Tracer

In this activity, you see how Packet Tracer uses the O S I Model as a reference to display the encapsulation details of several TCP/IP protocols.

2.5 Network Addressing

2.5.1 Addressing in the Network

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The OSI model describes the processes of encoding, formatting, segmenting, and encapsulating data for transmission over the network. A data stream that is sent from a source to a destination can be divided into pieces and interleaved with messages traveling from other hosts to other destinations. Billions of these pieces of information are traveling over a network at any given time. It is critical for each piece of data to contain enough identifying information to get it to the correct destination.

There are various types of addresses that must be included to successfully deliver the data from a source application running on one host to the correct destination application running on another. Using the OSI model as a guide, we can see the different addresses and identifiers that are necessary at each layer.

2.5.1 - Addressing in the Network
The diagram depicts functions and addressing at each layer of the O S I model. Layers 5, 6, and 7 are grouped together and referred to as Upper Layers.

- Upper Layers - Encoded Application Data
- Transport - Destination and Source Process Number (ports)
- Network - Destination and Source Logical Network Addresses
- Data Link - Destination and Source Physical Addresses
- Physical - Timing and Synchronization Bits

2.5.2 Getting the Data to the End Device

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During the process of encapsulation, address identifiers are added to the data as it travels down the protocol stack on the source host. Just as there are multiple layers of protocols that prepare the data for transmission to its destination, there are multiple layers of addressing to ensure its delivery.

The first identifier, the host physical address, is contained in the header of the Layer 2 PDU, called a frame. Layer 2 is concerned with the delivery of messages on a single local network. The Layer 2 address is unique on the local network and represents the address of the end device on the physical media. In a LAN using Ethernet, this address is called the Media Access Control (MAC) address. When two end devices communicate on the local Ethernet network, the frames that are exchanged between them contain the destination and source MAC addresses. Once a frame is successfully received by the destination host, the Layer 2 address information is removed as the data is decapsulated and moved up the protocol stack to Layer 3.

2.5.2 - Getting the Data to the End Device
The diagram depicts two PC's connected by a cloud labeled "Network". The PDU header contains device address fields: the destination device address, source device address, and the data from the source device. These are Layer 2 device hardware addresses.

2.5.3 Getting the Data through the Internetwork

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Layer 3 protocols are primarily designed to move data from one local network to another local network within an internetwork. Whereas Layer 2 addresses are only used to communicate between devices on a single local network, Layer 3 addresses must include identifiers that enable intermediary network devices to locate hosts on different networks. In the TCP/IP protocol suite, every IP host address contains information about the network where the host is located.

At the boundary of each local network, an intermediary network device, usually a router, decapsulates the frame to read the destination host address contained in the header of the packet, the Layer 3 PDU. Routers use the network identifier portion of this address to determine which path to use to reach the destination host. Once the path is determined, the router encapsulates the packet in a new frame and sends it on its way toward the destination end device. When the frame reaches its final destination, the frame and packet headers are removed and the data moved up to Layer 4.

2.5.3 - Getting the Data through the Internetwork
The diagram depicts an IP phone labeled "Source end device" (IP address 209.165.202.130), which is connected through three routers to a PC destination device (IP address 209.165.200.230). In addition to the Layer 2 addresses, the PC and IP Phone PDU's also contain the Layer 3 IP source and destination addresses, each of which consists of a network portion and a host (device) portion. A PDU is shown above the diagram with a destination IP network address of 209.165.200 and device (host) address of .230 for the PC. (These two combined create the PC IP address). The IP phone has a source network address of 209.165.202 and device (host) address of 130. (These two combined create the IP phone IP address). The IP address of the router interface for the source network is 209.165.202.145, and the IP address of the router interface for the destination network is 209.165.200.226.

2.5.4 Getting the Data to the Right Application

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At Layer 4, information contained in the PDU header does not identify a destination host or a destination network. What it does identify is the specific process or service running on the destination host device that will act on the data being delivered. Hosts, whether they are clients or servers on the Internet, can run multiple network applications simultaneously. People using PCs often have an e-mail client running at the same time as a web browser, an instant messaging program, some streaming media, and perhaps even a game. All these separately running programs are examples of individual processes.

Viewing a web page invokes at least one network process. Clicking a hyperlink causes a web browser to communicate with a web server. At the same time, in the background, an e-mail client may be sending and receiving email, and a colleague or friend may be sending an instant message.

Think about a computer that has only one network interface on it. All the data streams created by the applications that are running on the PC enter and leave through that one interface, yet instant messages do not popup in the middle of word processor document or e-mail showing up in a game.

This is because the individual processes running on the source and destination hosts communicate with each other. Each application or service is represented at Layer 4 by a port number. A unique dialogue between devices is identified with a pair of Layer 4 source and destination port numbers that are representative of the two communicating applications. When the data is received at the host, the port number is examined to determine which application or process is the correct destination for the data.

2.5.4 - Getting the Data to the Right Application
The animation depicts a PC connected to a server. The server is running three services: file transfer, terminal session, and e-mail. File-transfer data from the PC is directed to the file transfer service port number, and terminal session data from the PC is directed to the terminal session service port number. Electronic mail from the PC is directed to the email service port number. The caption states: "At the end device, the service port number directs the data to the correct conversation."

2.5.5 Warriors of the Net

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An entertaining resource to help you visualize networking concepts is the animated movie "Warriors of the Net" by TNG Media Lab. Before viewing the video, there are a few things to consider. First, in terms of concepts you have learned in this chapter, think about when in the video you are on the LAN, on WAN, on intranet, on Internet; and what are end devices versus intermediate devices; how the OSI and TCP/IP models apply; what protocols are involved.

Second, some terms are mentioned in the video which may not be familiar. The types of packets mentioned refers to the type of upper level data (TCP, UDP, ICMP Ping, PING of death) that is encapsulated in the IP Packets (everything is eventually converted into IP Packets). The devices the packet encounters on its journey are router, proxy server, router switch, corporate intranet, the proxy, URL, firewall, bandwidth, hosts, web server.

Third, while port numbers 21, 23, 25, 53, and 80 are referred to explicitly in the video, IP addresses are referred to only implicitly - can you see where? Where in the video might MAC addresses have been involved?

Finally, though all animations often have simplifications in them, there is one outright error in the video. About 5 minutes in, the statement is made "What happens when Mr. IP doesn't receive an acknowledgement, he simply sends a replacement packet." As you will find out in later chapters, this is not a function of the Layer 3 Internet Protocol, which is an "unreliable", best effort delivery protocol, but rather a function of the Transport Layer TCP Protocol.

By the end of this course you will have a much better understanding of the breadth and depth of the concepts depicted in the video. We hope you enjoy it.

Download the movie from http://www.warriorsofthe.net

2.5.5 - Warriors of the Net
The diagram depicts a screenshot from the Warriors of the Net video showing the router directing traffic.

2.6 Chapter Labs

2.6.1 Lab: Topology Orientation and Building a Small Network

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This lab begins by having you construct two small networks. It then shows how they are connected to the larger hands-on lab network used throughout the course. This network is a simplified model of a section of the Internet and will be used to develop your practical networking skills.

The following sequence of labs will introduce the networking terms below. This networking terminology will be studied in detail in subsequent chapters.

Straight-through Cable: Unshielded twisted pair (UTP) copper cable for connecting dissimilar networking devices

Crossover Cable: UTP copper cable for connecting similar networking devices

Serial Cable: Copper cable typical of wide area connections

Ethernet: Dominant local area network technology

MAC Address: Ethernet Layer 2, physical address

IP Address: Layer 3 logical address

Subnet Mask: Required to interpret the IP address

Default Gateway: The IP address on a router interface to which a network sends traffic leaving the local network

NIC: Network Interface Card, the port or interface that allows an end device to participate in a network

Port (hardware): An interface that allows a networking device to participate in network and to be connected via networking media

Port (software): Layer 4 protocol address in the TCP/IP suite

Interface (hardware): A port

Interface (software): A logical interaction point within software

PC: End device

Computer: End device

Workstation: End device

Switch: Intermediate device which makes decision on frames based on Layer 2 addresses (typical Ethernet MAC addresses)

Router: Layer 3, 2, and 1 device which makes decisions on packets based on Layer 3 addresses (typically IPv4 addresses)

Bit: Binary digit, logical 1 or zero, has various physical representations as electrical, optical, or microwave pulses; Layer 1 PDU

Frame: Layer 2 PDU

Packet: Layer 3 PDU

Click the Lab Icon for more details.

2.6.1 - Topology Orientation and Building a Small Network
Link to Hands-on Lab: Topology Orientation and Building a Small Network

This lab begins by having you construct two small networks. It then shows how they are connected to the larger hands-on lab network used throughout the course. This network is a simplified model of a section of the Internet and will be used to develop your practical networking skills.

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In this activity, you will use Packet Tracer to complete the Topology Orientation and Building a Small Network lab.

Click the Packet Tracer icon to launch the Packet Tracer activity.

2.6.1 - Topology Orientation and Building a Small Network
Link to Packet Tracer Activity: Topology Orientation and Building a Small Network

In this activity, you use Packet Tracer to complete the Topology Orientation and Building a Small Network lab.

2.6.2 Lab: Using Wireshark™ to View Protocol Data Units

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In this lab, you will learn to use the very powerful Wireshark tool by capturing ("sniffing") traffic off of the model network.

Click the Lab Icon for more details.

2.6.2 - Using Wireshark to View Protocol Data Units
Link to Hands-on Lab: Using Wireshark to View Protocol Data Units
In this lab, you learn to use the very powerful Wireshark tool by capturing (sniffing) traffic off of the model network.

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In this activity, you will use Packet Tracer's Simulation mode to capture and analyze packets from a ping from a PC's command prompt and a web request using a URL.

Click the Packet Tracer icon to launch the Packet Tracer activity.

2.6.2 - Using Wireshark to View Protocol Data Units
Link to Packet Tracer Activity: Using Packet Tracer to View Protocol Data Units

In this activity, you use Packet Tracer's Simulation mode to capture and analyze packets from a ping from a PC's command prompt and a web request using a URL.

2.7 Chapter Summary

2.7.1 Summary and Review

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Data networks are systems of end devices, intermediary devices, and the media connecting the devices, which provide the platform for the human network.

These devices, and the services that operate on them, can interconnect in a global and user-transparent way because they comply with rules and protocols.

The use of layered models as abstractions means that the operations of network systems can be analyzed and developed to cater the needs of future communication services.

The most widely-used networking models are OSI and TCP/IP. Associating the protocols that set the rules of data communications with the different layers is useful in determining which devices and services are applied at specific points as data passes across LANs and WANs.

As it passes down the stack, data is segmented into pieces and encapsulated with addresses and other labels. The process is reversed as the pieces are decapsulated and passed up the destination protocol stack.

Applying models allows various individuals, companies, and trade associations to analyze current networks and plan the networks of the future.

2.7.1 - Summary and Review
In this chapter, you learned to:
- Describe the structure of a network, including the devices and media that are necessary for successful communication.
- Explain the function of protocols in network communications.
- Explain the advantages of using a layered model to describe network functionality.
- Describe the role of each layer in two recognized network models: the TCP/IP model and the O S I model.
- Describe the importance of addressing and naming schemes in network communications.

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2.7.1 - Summary and Review
This is a review and is not a quiz. Questions and answers are provided.
Question 1. List five end devices, six intermediate devices, and three forms of networking media.
Answer:
- End devices: desktop computer, laptop computer, server, PDA, cellular mobile phone, printer, security camera, IP phone, electronic point of sale device, automatic teller machine.
- Intermediate device: repeater, hub, wireless access point, switch, router, modem, firewall devices.
- Networking media: copper cable, fiber cable, radio (wireless).

Question 2. Compare and contrast the following terms: network, LAN, WAN, internetwork, and Internet.
Answer:
Network - A group of interconnected devices capable of carrying many different types of communications, including traditional computer data, interactive voice, video, and entertainment products.

LAN - A local network or group of interconnected local networks that are under the same administrative control. In the past, LAN's were thought of only as small networks that existed in a single physical location. While LAN's can be as small as a single local network installed in a home or small office, they now also include interconnected local networks consisting of many hundreds of hosts, installed in multiple buildings and locations. All local networks within a LAN are under one administrative control group that governs the security and access control policies that are in force on the network.

WAN - Telecommunications service providers (TSP) operate large regional networks spanning long distances. Individual organizations usually lease connections through a telecommunications service provider network. These networks that connect LAN's in geographically separated locations are wide area networks (WAN's). Although the organization maintains all policies and administration of the LAN's at both ends of the connection, the policies within the communications service provider network are controlled by the TSP. WAN's use specifically designed network devices to make the interconnections between LAN's.

Internetwork - A mesh of interconnected networks is used. Some of these interconnected networks are owned by large public and private organizations, such as government agencies or industrial enterprises, and are reserved for their exclusive use. The most well-known and widely used publicly accessible internetwork is the Internet.

Internet - The most well-known and widely used publicly accessible internetwork. The Internet is created by the interconnection of networks belonging to Internet Service Providers (ISP's). These ISP networks connect to each other to provide access for users all over the world. Ensuring effective communication across this diverse infrastructure requires the application of consistent and commonly recognized technologies and protocols as well as the cooperation of many network administration agencies.

Question 3. Compare and contrast the layers of the O S I model with the TCP/IP protocol stack.
Answer: There are two basic types of networking models: protocol models and reference models.

A protocol model closely matches the structure of a particular protocol suite. The hierarchical set of related protocols in a suite represents all the functionality required to interface the human network with the data network. The four-layer TCP/IP model is a protocol model because it describes the functions that occur at each layer of protocols within the TCP/IP suite.

A reference model provides a common reference for maintaining consistency within all types of network protocols and services. A reference model is not intended to be an implementation specification or to provide a sufficient level of detail to define precisely the services of the network architecture. The primary purpose of a reference model is to aid in clearer understanding of the functions and process involved. The seven-layer Open Systems Interconnection (O S I) model is the most widely known internetwork reference model. It is used for data network design, operation specifications, and troubleshooting.

The protocols that make up the TCP/IP protocol suite can be described in terms of the O S I reference model. In the O S I model, the Network Access Layer and the Application Layer of the TCP/IP model are further divided to describe discreet functions that need to occur at these layers.

At the Network Access Layer, the TCP/IP protocol suite does not specify which protocols to use when transmitting over a physical medium; it only describes the handoff from the Internet Layer to the physical network protocols. The O S I Layers 1 and 2 discuss the necessary procedures to access the media and the physical means to send data over a network.

The key parallels between the two network models occur at the O S I model Layers 3 and 4. O S I Model Layer 3, the Network Layer, almost universally is used to discuss and document the range of processes that occur in all data networks to address and route messages through an internetwork. The Internet Protocol (IP) is the TCP/IP suite protocol that includes the functionality described at Layer 3.

Layer 4, the Transport Layer of the O S I model, is often used to describe general services or functions that manage individual conversations between source and destination hosts. These functions include acknowledgement, error recovery, and sequencing. At this layer, the TCP/IP protocols Transmission Control Protocol (TCP) and User Datagram Protocol (UDP) provide the necessary functionality.

The TCP/IP Application Layer includes a number of protocols that provide specific functionality to a variety of end-user applications. The O S I model Layers 5, 6, and 7 are used as references for application software developers and vendors to produce products that need to access networks for communications.

Question 4. Explain why networking models are used.
Answer: Although the TCP/IP and O S I models are the primary models used when discussing network functionality, designers of network protocols, services, or devices can create their own models to represent their products. Ultimately, designers are required to communicate to the industry by relating their product or service to either the O S I model or the TCP/IP model, or to both.

As a reference model, the O S I model provides an extensive list of functions and services that can occur at each layer. It also describes the interaction of each layer with the layers directly above and below it. Whereas TCP/IP model layers are referred to by name, the seven O S I model layers are usually referred to by number.

There are benefits to using a layered model to describe network protocols and operations:
- Assists in protocol design, because protocols that operate at a specific layer have defined information that they act upon and a defined interface to the layers above and below.
- Fosters competition because products from different vendors can work together.
- Prevents technology or capability changes in one layer from affecting other layers above and below.
- Provides a common language to describe networking functions and capabilities.

Question 5. Elaborate on the following terms: protocol, PDU's, and encapsulation.
Answer:
Protocol:
All communication, whether face-to-face or over a network, is governed by predetermined rules called protocols. These protocols are specific to the characteristics of the conversation. In our day-to-day personal communication, the rules we use to communicate over one medium, like a telephone call, are not necessarily the same as the protocols for using another medium, such as sending a letter.

Successful communication between hosts on a network requires the interaction of many different protocols. A group of inter-related protocols that are necessary to perform a communication function is called a protocol suite. These protocols are implemented in software and hardware that is on each host and network device.

PDU and Encapsulation:
As application data is passed down the protocol stack on its way to be transmitted across the network media, various protocols add information to it at each level. This is commonly known as the encapsulation process.
The form that a piece of data takes at any layer is called a Protocol Data Unit (PDU). During encapsulation, each succeeding layer encapsulates the PDU that it receives from the layer above in accordance with the protocol being used. At each stage of the process, a PDU has a different name to reflect its new appearance. PDU's within the protocols of the TCP/IP suite are:
- Data - The general term for the PDU used at the Application Layer.
- Segment - Transport Layer PDU
- Packet - Internetwork Layer PDU
- Frame - Network Access Layer PDU

Question 6. Explain the postal metaphor for encapsulation.
Answer: Individual pages of a letter are written and numbered sequentially. Each page is sealed in a separate envelope that is then addressed to the recipient. The letters are posted and put in a mailbag (labeled with the destination) with many other envelopes, each containing a page of different letters and addressed to recipients. Many mailbags are loaded into a van and transported toward the destination. Along the way, the mailbags might be transferred to other vans or different modes of transport - trucks, trains, aircraft, ships. At the destination, the mailbags are unloaded and emptied. The envelopes are delivered to the destination addresses. At one address, all the envelopes received are opened, the page are removed from each one, and the pages are reassembled into the letter.

The envelope, the mailbag, and the vans, trucks, or aircraft, do not care what is in the container that they carry. The letter itself is not used to provide information to assist in its delivery. The address on the envelope, the label on the mailbag, or the delivery instructions to the van driver are what direct the letter toward its destination.

Data encapsulation follows the same principle. It is the addresses used in each layer of encapsulation that direct the data toward its destination, not the data itself.

Question 7. What are the unique roles of Layer 2, Layer 3, and Layer 4 addresses?
Answer:
- Layer 4 addresses (ports) identify the individual applications sending or receiving data.
- Layer 3 (logical) addresses identify devices and their networks.
- Layer 2 (physical) addresses identify devices on a local network.

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In this activity, you will start building, testing, and analyzing a model of the Exploration lab network.

Packet Tracer Skills Integration Instructions (PDF)

Click the Packet Tracer icon to launch the Packet Tracer activity.

2.7.1 - Summary and Review
Link to Packet Tracer Activity: Skills Integration Challenge: Examining Packets

In this activity, you start building, testing, and analyzing a model of the Exploration lab network.

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To Learn More
Reflection Questions

How are the classifications LAN, WAN, and Internet still useful, and how might they actually be problematic in classifying networks?

What are strengths and weaknesses of the OSI and TCP/IP models? Why are both models still used?

Metaphors and analogies can be powerful aids to learning but must be used with care. Consider issues of devices, protocols, and addressing in the following systems:

• Standard postal service
• Express parcel delivery service
• Traditional (analog) telephone system
• Internet telephony
• Containerized shipping services
• Terrestrial and satellite radio systems
• Broadcast and cable television

Discuss what you see as common factors among these systems. Apply any similarities to other networks.

How could you apply these common concepts to developing new communications systems and networks?

2.7.1 - Summary and Review
The diagram depicts a collage of people using computers and networks.

2.8 Chapter Quiz

2.8.1 Chapter Quiz

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2.8.1 - Chapter Quiz
1.Which O S I layer is associated with IP addressing?
A.1
B.2
C.3
D.4

2.Which type of addressing is found at the O S I Layer 2? (Choose two.)
A.logical
B.physical
C.MAC
D.IP
E.port

3.When a server responds to a web request, what occurs next in the encapsulation process after the web page data is formatted and separated into TCP segments?
A.The client de-encapsulates the segment and opens the web page.
B.The client adds the appropriate physical addresses to the segments so that the server can forward the data.
C.The server converts the data to bits for transport across the medium.
D.The server adds the source and destination IP address to each segment header to deliver the packets to the destination.
E.The server adds the source and destination physical addresses to the packet header.

4.Which term describes a specific set of rules that determines the formatting of messages and the process of encapsulation used to forward data?
A.segmentation
B.protocol
C.multiplexing
D.Q o S
E.reassembly

5.Which two are protocols associated with Layer 4 of the O S I model? (Choose two.)
A.IP
B.TCP
C.FTP
D.TFTP
E.UDP

6.Match the terms with their corresponding definition. (Not all items are used.)
Terms:
A. Multiplexing
B. PDU
C. Q o S
D. Encapsulation
E. Segmentation
F. Protocol

Definitions:
One. Dividing data streams into smaller pieces suitable for transmission.
Two. The process of adding layer-specific information or labels necessary to transmit data.
Three. Interleaving multiple data streams onto a shared communication channel or network medium.
Four. Formal rules outlining the structure and process of network communication.
Five. Term used for a data packet, often implying a specific layer or protocol.

7.Match the networking terms to the appropriate O S I layer. (Not all terms are used.)
Terms:
Frames
IP address
MAC address
Logical addressing
Packets
Physical addressing
Port numbers
Segments
Bits
Sequence numbers

Layers:
Transport
Network
Data Link

8.Match the functional description of each O S I layer to the appropriate name of the layer.
Descriptions:
A. Defines procedures for accessing the media.
B. Standardizes the data formats between systems.
C. Routes packets according to a unique network address.
D. Cabling, voltages, bits, and data rates.
E. Manages users sessions and dialogues.
F. Defines interfaces between application software.
G. End-to-end message delivery over the network.

Layers:
Seven. Application
Six. Presentation
Five. Session
Four. Transport
Three. Network
Two. Data Link
One. Physical