Chapter 2: Network Models PDF

Summary

This document describes network models. It uses postal service as an example to illustrate the concept of layers in daily life. It also details the OSI model and the functions of each layer in the model, along with describing the TCP/IP protocol suite.

Full Transcript

Chapter 2
Network Models

2.1 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
 2-1 LAYERED TASKS

We use the concept of layers in our daily life. As an
example, let us consider two friends who communicate
through postal mail. The process of sending a letter to a
friend would be complex if there were no services
available from the post office.

Topics discussed in this section:
Sender, Receiver, and Carrier
Hierarchy

2.2
 Figure 2.1 Tasks involved in sending a letter

2.3
 2-2 THE OSI MODEL
Established in 1947, the International Standards
Organization (ISO) is a multinational body dedicated to
worldwide agreement on international standards. An ISO
standard that covers all aspects of network
communications is the Open Systems Interconnection
(OSI) model. It was first introduced in the late 1970s.

Topics discussed in this section:
Layered Architecture
Peer-to-Peer Processes
Encapsulation

2.4
 Note

ISO is the organization.
OSI is the model.

2.5
 Figure 2.2 Seven layers of the OSI model

2.6
 Figure 2.3 The interaction between layers in the OSI model

2.7
 Figure 2.4 An exchange using the OSI model

2.8
 2-3 LAYERS IN THE OSI MODEL

In this section we briefly describe the functions of each
layer in the OSI model.

Topics discussed in this section:
Physical Layer
Data Link Layer
Network Layer
Transport Layer
Session Layer
Presentation Layer
Application Layer

2.9
 Figure 2.5 Physical layer

2.10
 Note

The physical layer is responsible for movements of
individual bits from one hop (node) to the next.

2.11
 Physical Layer
Physical characteristics of interfaces and medium

Interface between the devices and the transmission medium.

Defines the type of transmission medium.
Representation of bits

The type of encoding (how 0’s and 1’s are changed to signals).
Data rate

The number of bits sent each second.
Synchronization of bits

The sender and the receiver clocks must be synchronized.
Line configuration

Connection of devices to the medium (point to point or
multipoint configuration).
Physical topology

How devices are connected to make a network.
Transmission mode

Simplex, half-duplex, or full-duplex.

2.12
 Figure 2.6 Data link layer

2.13
 Note

The data link layer is responsible for moving
frames from one hop (node) to the next.

2.14
 Data Link Layer
Framing

Dividing the stream of bits received from the network layer
into manageable data units called frames.
Physical Addressing

Defining the sender and/or the receiver of the frame.

Station on the network or the device that connects the network
to the next one.
Flow Control

Controlling the transmission speed of the sender (across a
single link).
Error Control

Detecting and retransmitting damaged or lost frames (across a
single link).

Recognizing duplicate frames.
Access Control

Which device has control over the link at any given time.

2.15
 Figure 2.7 Hop-to-hop delivery

2.16
 Figure 2.8 Network layer

2.17
 Note

The network layer is responsible for the
delivery of individual packets from
the source host to the destination host.

2.18
 Network Layer
Logical Addressing
Adding logical addresses of the sender
and receiver.
Routing
Routing or switching the packets to their
final destination

2.19
 Figure 2.9 Source-to-destination delivery

2.20
 Figure 2.10 Transport layer

2.21
 Note

The transport layer is responsible for the delivery
of a message from one process to another.

2.22
 Transport Layer
Service-Point Addressing

The address of the process (running program) on a
computer.
Segmentation and Reassembly

Division of a message into segments.

Adding sequence numbers to reassemble the
message correctly at the destination.
Connection Control

Connectionless or connection-oriented.
Flow Control

End to end flow control.
Error Control

End to end error control.

2.23
 Figure 2.11 Reliable process-to-process delivery of a message

2.24
Figure 2.12 Session layer

2.25
 Note

The session layer is responsible for dialog
control and synchronization.

2.26
 Figure 2.13 Presentation layer

2.27
 Session layer
Dialog control
Half-duplex or full-duplex.
Synchronization
Adding checkpoints synchronization
points to a stream of data.

2.28
 Note

The presentation layer is responsible for translation,
compression, and encryption.

2.29
 Presentation layer
Translation

Changing information

Sender-dependent format -> common format ->
receiver dependent format.
Encryption

Sensitive information.

Transforming the original information to another form
and sending the resulting message out over the
network.

Decryption: Transforming the message back to its
original form.
Compression

Reducing the number of bits contained in the
information.

Important in the transmission of multimedia.

2.30
 Figure 2.14 Application layer

2.31
 Note

The application layer is responsible for
providing services to the user.

2.32
 Application Layer
Network Virtual Terminal
Allows the user to log on to a remote host.
File Transfer, Access and Management
Allows the user to access files in a remote
host.
Mail Services
Provides the basis for email forwarding and
storage.
Directory Services
Provides distributed database sources and
access for global information.

2.33
 Figure 2.15 Summary of layers

2.34
 2-4 TCP/IP PROTOCOL SUITE

The layers in the TCP/IP protocol suite do not exactly
match those in the OSI model. The original TCP/IP
protocol suite was defined as having four layers: host-to-
network, internet, transport, and application. However,
when TCP/IP is compared to OSI, we can say that the
TCP/IP protocol suite is made of five layers: physical,
data link, network, transport, and application.

Topics discussed in this section:
Physical and Data Link Layers
Network Layer
Transport Layer
Application Layer
2.35
 Figure 2.16 TCP/IP and OSI model

2.36
 Network Layer
Internetworking Protocol (IP)
Unreliable and connectionless protocol.
Best effort delivery (it tries to get a
transmission through to its destination
but with no guarantees.
Transports data in packets called
datagrams.

2.37
 Four supporting protocols:
Address Resolution Protocol (ARP).

Is used to find the physical address of the
node when its internet address is known.
Reverse Address Resolution Protocol
(RARP)

Allows a host to discover its Internet address
when it knows only its physical address.
Internet Control Message Protocol (ICMP)

Sends query and error reporting messages.
Internet Group Message Protocol (IGMP)

Facilitates the simultaneous transmission of
a message to group of recipients.

2.38
 Transport Layer
User Datagram Protocol (UDP)
Unreliable delivery.
Connectionless.
Transmission Control Protocol (TCP)
Reliable delivery.
Connection-oriented.
Stream Control Transmission Protocol
(SCTP)
Provides support for newer applications such as
VOIP.
Combines the best features of UDP and TCP.

2.39
 2-5 ADDRESSING

Four levels of addresses are used in an internet employing
the TCP/IP protocols: physical, logical, port, and specific.

Topics discussed in this section:
Physical Addresses
Logical Addresses
Port Addresses
Specific Addresses

2.40
 Figure 2.17 Addresses in TCP/IP

2.41
 Figure 2.18 Relationship of layers and addresses in TCP/IP

2.42
 Example 2.1

In Figure 2.19 a node with physical address 10 sends a
frame to a node with physical address 87. The two nodes
are connected by a link (bus topology LAN). As the
figure shows, the computer with physical address 10 is
the sender, and the computer with physical address 87 is
the receiver.

2.43
 Figure 2.19 Physical addresses

2.44
 Example 2.2

As we will see in Chapter 13, most local-area networks
use a 48-bit (6-byte) physical address written as 12
hexadecimal digits; every byte (2 hexadecimal digits) is
separated by a colon, as shown below:

07:01:02:01:2C:4B

A 6-byte (12 hexadecimal digits) physical address.

2.45
 Example 2.3

Figure 2.20 shows a part of an internet with two routers
connecting three LANs. Each device (computer or
router) has a pair of addresses (logical and physical) for
each connection. In this case, each computer is
connected to only one link and therefore has only one
pair of addresses. Each router, however, is connected to
three networks (only two are shown in the figure). So
each router has three pairs of addresses, one for each
connection.

2.46
 Figure 2.20 IP addresses

2.47
 Example 2.4

Figure 2.21 shows two computers communicating via the
Internet. The sending computer is running three
processes at this time with port addresses a, b, and c. The
receiving computer is running two processes at this time
with port addresses j and k. Process a in the sending
computer needs to communicate with process j in the
receiving computer. Note that although physical
addresses change from hop to hop, logical and port
addresses remain the same from the source to
destination.

2.48
 Figure 2.21 Port addresses

2.49
 Note

The physical addresses will change from hop to hop,
but the logical addresses usually remain the same.

2.50
 Example 2.5

As we will see in Chapter 23, a port address is a 16-bit
address represented by one decimal number as shown.

753

A 16-bit port address represented
as one single number.

2.51
 Note

The physical addresses change from hop to hop,
but the logical and port addresses usually remain the same.

2.52
 Specific address
User-friendly addresses.
Email address (e.g.
[email protected]).
Universal Resource Locator (URL)
(e.g. www.mhhe.com)
Gets changed to the corresponding
port and logical addresses by the
sending computer.

2.53