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CCNA Routing and Switching Complete Study Guide. Todd LammleЧитать онлайн книгу.

CCNA Routing and Switching Complete Study Guide - Todd Lammle


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the Application layer. So basically, the Application layer is working as the interface between the actual application program and the next layer down by providing ways for the application to send information down through the protocol stack. This isn’t actually part of the layered structure, because browsers don’t live in the Application layer, but they interface with it as well as the relevant protocols when asked to access remote resources.

      Identifying and confirming the communication partner’s availability and verifying the required resources to permit the specified type of communication to take place also occurs at the Application layer. This is important because, like the lion’s share of browser functions, computer applications sometimes need more than desktop resources. It’s more typical than you would think for the communicating components of several network applications to come together to carry out a requested function. Here are a few good examples of these kinds of events:

      ■ File transfers

      ■ Email

      ■ Enabling remote access

      ■ Network management activities

      ■ Client/server processes

      ■ Information location

      Many network applications provide services for communication over enterprise networks, but for present and future internetworking, the need is fast developing to reach beyond the limits of current physical networking.

       The Application layer works as the interface between actual application programs. This means end-user programs like Microsoft Word don’t reside at the Application layer, they interface with the Application layer protocols. Later, in Chapter 3, “Introduction to TCP/IP,” I’ll talk in detail about a few important programs that actually reside at the Application layer, like Telnet, FTP, and TFTP.

      The Presentation Layer

      The Presentation layer gets its name from its purpose: It presents data to the Application layer and is responsible for data translation and code formatting. Think of it as the OSI model’s translator, providing coding and conversion services. One very effective way of ensuring a successful data transfer is to convert the data into a standard format before transmission. Computers are configured to receive this generically formatted data and then reformat it back into its native state to read it. An example of this type of translation service occurs when translating old Extended Binary Coded Decimal Interchange Code (EBCDIC) data to ASCII, the American Standard Code for Information Interchange (often pronounced “askee”). So just remember that by providing translation services, the Presentation layer ensures that data transferred from the Application layer of one system can be read by the Application layer of another one.

      With this in mind, it follows that the OSI would include protocols that define how standard data should be formatted, so key functions like data compression, decompression, encryption, and decryption are also associated with this layer. Some Presentation layer standards are involved in multimedia operations as well.

      The Session Layer

      The Session layer is responsible for setting up, managing, and dismantling sessions between Presentation layer entities and keeping user data separate. Dialog control between devices also occurs at this layer.

      Communication between hosts’ various applications at the Session layer, as from a client to a server, is coordinated and organized via three different modes: simplex, half-duplex, and full-duplex. Simplex is simple one-way communication, kind of like saying something and not getting a reply. Half-duplex is actual two-way communication, but it can take place in only one direction at a time, preventing the interruption of the transmitting device. It’s like when pilots and ship captains communicate over their radios, or even a walkie-talkie. But full-duplex is exactly like a real conversation where devices can transmit and receive at the same time, much like two people arguing or interrupting each other during a telephone conversation.

      The Transport Layer

      The Transport layer segments and reassembles data into a single data stream. Services located at this layer take all the various data received from upper-layer applications, then combine it into the same, concise data stream. These protocols provide end-to-end data transport services and can establish a logical connection between the sending host and destination host on an internetwork.

      A pair of well-known protocols called TCP and UDP are integral to this layer, but no worries if you’re not already familiar with them because I’ll bring you up to speed later, in Chapter 3. For now, understand that although both work at the Transport layer, TCP is known as a reliable service but UDP is not. This distinction gives application developers more options because they have a choice between the two protocols when they are designing products for this layer.

      The Transport layer is responsible for providing mechanisms for multiplexing upper-layer applications, establishing sessions, and tearing down virtual circuits. It can also hide the details of network-dependent information from the higher layers as well as provide transparent data transfer.

       The term reliable networking can be used at the Transport layer. Reliable networking requires that acknowledgments, sequencing, and flow control will all be used.

      The Transport layer can be either connectionless or connection-oriented, but because Cisco really wants you to understand the connection-oriented function of the Transport layer, I’m going to go into that in more detail here.

      Connection-Oriented Communication

      For reliable transport to occur, a device that wants to transmit must first establish a connection-oriented communication session with a remote device – its peer system – known as a call setup or a three-way handshake. Once this process is complete, the data transfer occurs, and when it’s finished, a call termination takes place to tear down the virtual circuit.

Figure 1.10 depicts a typical reliable session taking place between sending and receiving systems. In it, you can see that both hosts’ application programs begin by notifying their individual operating systems that a connection is about to be initiated. The two operating systems communicate by sending messages over the network confirming that the transfer is approved and that both sides are ready for it to take place. After all of this required synchronization takes place, a connection is fully established and the data transfer begins. And by the way, it’s really helpful to understand that this virtual circuit setup is often referred to as overhead!

Diagram shows the transmission of SYN, SYN/ ACK and ACK signals, connection establishment and data transfer between sender and receiver systems.

FIGURE 1.10 Establishing a connection-oriented session

      Okay, now while the information is being transferred between hosts, the two machines periodically check in with each other, communicating through their protocol software to ensure that all is going well and that the data is being received properly.

      Here’s a summary of the steps in the connection-oriented session – that three-way handshake – pictured in Figure 1.9:

      ■ The first “connection agreement” segment is a request for synchronization (SYN).

      ■ The next segments acknowledge (ACK) the request and establish connection parameters – the rules – between hosts. These segments request that the receiver’s sequencing is synchronized here as well so that a bidirectional connection can be formed.

      ■ The final segment is also an acknowledgment, which notifies the destination host that the connection agreement has been accepted and that the actual connection has been established. Data transfer can now begin.

      Sounds pretty simple, but things don’t always flow so smoothly. Sometimes during a transfer, congestion can occur because a high-speed computer is generating data traffic a lot faster than the network


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