Protocols and Models PDF

Summary

This document provides an overview of network protocols and models. It details the objectives of network protocols, including the rules, protocols, protocol suites and standards organizations. It also covers communications fundamentals, and various network protocol functions, types, interactions, and data encapsulation.

Full Transcript

Protocols and Models
ITEC 90 - NETWORK FUNDAMENTALS
 Objective
01 The Rules 05 Reference Models

02 Protocols 06 Data Encapsulation

03 Protocol Suites 07 Data Access

04 Standards Organizations
The Rules
 Communications Fundamentals
Networks can vary in size and complexity. It is not
enough to have a connection, devices must agree on
“how” to communicate.

There are three elements to any communication:
There will be a source (sender).
There will be a destination (receiver).
There will be a channel (media) that provides for the
path of communications to occur.
 Communications Protocols

All communications are governed by protocols.
Protocols are the rules that communications will
follow.
These rules will vary depending on the protocol.
 Sample 2

Sample 1
 Rule Establishment

Individuals must use established rules or
agreements to govern the conversation.
The first message is difficult to read because it is
not formatted properly. The second shows the
message properly formatted
Rule Establishment
 Rule Establishment
Protocols must account for the following
requirements:
An identified sender and receiver
Common language and grammar
Speed and timing of delivery
Confirmation or acknowledgment
requirements
 Network Protocol Requirements
Common computer protocols must be in
agreement and include the following
requirements:
Message encoding
Message formatting and encapsulation
Message size
Message timing
Message delivery options
 Message Encoding

Encoding is the process of converting
information into another acceptable form for
transmission.
Decoding reverses this process to interpret
the information.
 Sample 2

Sample 1
 Message Formatting
and Encapsulation
When a message is sent, it must use a
specific format or structure.
Message formats depend on the type of
message and the channel that is used to
deliver the message.
 Message Size
Encoding between hosts must be in an appropriate
format for the medium.
Messages sent across the network are converted to
bits
The bits are encoded into a pattern of light, sound,
or electrical impulses.
The destination host must decode the signals to
interpret the message.
 Message Timing

Message timing includes the following:
1. Flow Control – Manages the rate of data transmission and
defines how much information can be sent and the speed at
which it can be delivered.
2. Response Timeout – Manages how long a device waits
when it does not hear a reply from the destination.
3. Access method - Determines when someone can send a
message.
 Message Delivery Options

Message delivery may one of the following methods:
Unicast – one to one communication
Multicast – one to many, typically not all
Broadcast – one to all

Note: Broadcasts are used in IPv4 networks, but are not an
option for IPv6. Later we will also see “Anycast” as an additional
delivery option for IPv6.
 A Note About the Node Icon

Documents may use the node icon , typically a circle, to
represent all devices.
The figure illustrates the use of the node icon for delivery
options.
Protocols
 Network Protocol Overview

Network protocols define a common set of rules.
Can be implemented on devices in:
Software
Hardware
Both
Protocols have their own:
Function
Format
Rules
 Protocol Type
1. Network Communications - enable two or more devices to
communicate over one or more networks.
2. Network Security - secure data to provide authentication,
data integrity, and data encryption.
3. Routing - enable routers to exchange route information,
compare path information, and select best path.
4. Service Discovery - used for the automatic detection of
devices or services
 Network Protocol Functions
Devices use agreed-upon protocols to communicate.
Protocols may have may have one or functions.
 Network Protocol Functions
1. Addressing - Identifies sender and receiver
2. Reliability - Provides guaranteed delivery
3. Flow Control - Ensures data flows at an efficient rate
4. Sequencing - Uniquely labels each transmitted segment of
data
5. Error Detection - Determines if data became corrupted
during transmission
6. Application Interface - Process-to-process communications
between network applications
 Protocol Interaction
Networks require the use of several protocols.
Each protocol has its own function and format.
 Protocol
1. Hypertext Transfer Protocol (HTTP) - It governs the way a web
server and a web client interact and it also defines content and
format.
2. Transmission Control Protocol (TCP) - It manages the
individual conversations, provides guaranteed delivery and
manages flow control.
3. Internet Protocol (IP) - Delivers messages globally from the
sender to the receiver.
4. Ethernet - Delivers messages from one NIC to another NIC on
the same Ethernet Local Area Network (LAN)
Protocol Suites
 Network Protocol Suites
Protocols must be able to work with other protocols.
Protocol suite:
A group of inter-related protocols necessary to perform a
communication function
Sets of rules that work together to help solve a problem

The protocols are viewed in terms of layers:
Higher Layers
Lower Layers- concerned with moving data and provide services
Network Protocol Suites
 Evolution of Protocol Suites

There are several protocol suites.
Internet Protocol Suite or TCP/IP- The most common protocol
suite and maintained by the Internet Engineering Task Force
(IETF)
Open Systems Interconnection (OSI) protocols- Developed
by the International Organization for Standardization (ISO) and
the International Telecommunications Union (ITU)
AppleTalk- Proprietary suite release by Apple Inc.
Novell NetWare- Proprietary suite developed by Novell Inc.
Evolution of Protocol Suites
 TCP/IP Protocol Example

TCP/IP protocols operate at
the application, transport,
and internet layers.
The most common network
access layer LAN protocols
are Ethernet and WLAN
(wireless LAN).
 TCP/IP Protocol Suite

TCP/IP is the protocol suite used by the internet and includes many
protocols.

TCP/IP is:
An open standard protocol suite that is freely available to the
public and can be used by any vendor
A standards-based protocol suite that is endorsed by the
networking industry and approved by a standards organization to
ensure interoperability
TCP/IP Protocol Suite
 TCP/IP Communication Process

A web server encapsulating and sending a web page to a client.
A client de-encapsulating the web page for the web browser
 Standards
Organizations
 Open Standards
Open standards encourage:
interoperability
competition
innovation

Standards organizations are:
vendor-neutral
non-profit organizations
established to develop and promote
the concept of open standards.
 Internet Standards
1. Internet Society (ISOC) - Promotes the open development
and evolution of internet
2. Internet Architecture Board (IAB) - Responsible for
management and development of internet standards
3. Internet Engineering Task Force (IETF) - Develops,
updates, and maintains internet and TCP/IP technologies
4. Internet Research Task Force (IRTF) - Focused on long-
term research related to internet and TCP/IP protocols
 Internet Standards
Standards organizations involved with the development and support
of TCP/IP

Internet Corporation for Assigned Names and Numbers
(ICANN)
Coordinates IP address allocation, the management of domain
names, and assignment of other information
Internet Assigned Numbers Authority (IANA)
Oversees and manages IP address allocation, domain name
management, and protocol identifiers for ICANN
Internet Standards
Electronic and Communications Standards
Institute of Electrical and Electronics Engineers (IEEE,
pronounced “I-triple-E”) dedicated to creating standards in
power and energy, healthcare, telecommunications, and
networking.

Electronic Industries Alliance (EIA) - develops standards
relating to electrical wiring, connectors, and the 19-inch racks
used to mount networking equipment
Electronic and Communications Standards
Telecommunications Industry Association (TIA) - develops
communication standards in radio equipment, cellular towers,
Voice over IP (VoIP) devices, satellite communications, and more.

International Telecommunications Union-Telecommunication
Standardization Sector (ITU-T) - defines standards for video
compression, Internet Protocol Television (IPTV), and broadband
communications, such as a digital subscriber line (DSL)
Reference Models
 The Benefits of Using a Layered Model

Complex concepts such as how a network operates can be
difficult to explain and understand. For this reason, a layered model
is used.
Two layered models describe network operations:
Open System Interconnection (OSI) Reference Model
TCP/IP Reference Model
 The Benefits of Using a Layered Model
These are the benefits of using a layered model:
Assist 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
Foster competition because products from different vendors can
work together
Prevent technology or capability changes in one layer from
affecting other layers above and below
Provide a common language to describe networking functions
and capabilities
 The OSI Reference Model
7 - Application - Contains protocols used for process-to-
process communications.
6 - Presentation - Provides for common representation of the
data transferred between application layer services.
5 - Session - Provides services to the presentation layer and to
manage data exchange.
4 - Transport - Defines services to segment, transfer, and
reassemble the data for individual communications.
 The OSI Reference Model

3 - Network - Provides services to exchange the individual
pieces of data over the network.
2 - Data Link - Describes methods for exchanging data frames
over a common media.
1 - Physical - Describes the means to activate, maintain, and
de-activate physical connections.
 The TCP/IP Reference Model
TCP/IP Model Layer
Application - Represents data to the user, plus encoding
and dialog control.
Transport - Supports communication between various
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.
 OSI and TCP/IP Model Comparison

The OSI model divides the network access layer and the
application layer of the TCP/IP model into multiple layers.
The TCP/IP protocol suite does not specify which protocols
to use when transmitting over a physical medium.
OSI Layers 1 and 2 discuss the necessary procedures to
access the media and the physical means to send data
over a network.
OSI and TCP/IP Model Comparison
Data Encapsulation
 Segmenting Messages
Segmenting is the process of breaking up messages into
smaller units. Multiplexing is the processes of taking multiple
streams of segmented data and interleaving them together.

Segmenting messages has two primary benefits:
Increases speed - Large amounts of data can be sent
over the network without tying up a communications link.
Increases efficiency - Only segments which fail to reach
the destination need to be retransmitted, not the entire
data stream.
Segmenting Messages
 Sequencing

Sequencing messages is the
process of numbering the segments so
that the
message may be reassembled at the
destination.
TCP is responsible for sequencing
the individual segments.
 Protocol Data Units
Encapsulation is the process where protocols add their information
to the data.
At each stage of the process, a PDU has a different name to
reflect its new functions.
There is no universal naming convention for PDUs, in this course, the
PDUs are named according to the protocols of the TCP/IP suite.
PDUs passing down the stack are as
follows:
- Data (Data Stream) - Segment
- Packet - Frame
- Bits (Bit Stream)
Protocol Data Units
 Encapsulation Example

Encapsulation is a top down process.
The level above does its process and then passes it
down to the next level of the model. This process is
repeated by each layer until it is sent out as a bit
stream.
Encapsulation Example
 De-encapsulation Example
Data is de-encapsulated as it moves up the stack.
When a layer completes its process, that layer strips off its
header and passes it up to the next level to be processed.
This is repeated at each layer until it is a data stream that
the application can process.
1. Received as Bits (Bit Stream)
2. Frame
3. Packet
4. Segment
5. Data (Data Stream)
De-encapsulation Example
Data Access
 Addresses
Both the data link and network layers use addressing to
deliver data from source to destination.
Network layer source and destination addresses
Responsible for delivering the IP packet from original source to
the final destination.
Data link layer source and destination addresses
Responsible for delivering the data link frame from one network
interface card (NIC) to another NIC on the same network.
Addresses
 Layer 3 Logical Address

The IP packet contains two IP addresses:
Source IP address - The IP address of the sending device,
original source of the packet.
Destination IP address - The IP address of the receiving
device, final destination of the packet. These addresses
may be on the same link or remote.
Layer 3 Logical Address
 Layer 3 Logical Address
An IP address contains two parts:
Network portion (IPv4) or Prefix (IPv6)
The left-most part of the address indicates the network
group which the IP address is a member.
Each LAN or WAN will have the same network portion.
Host portion (IPv4) or Interface ID (IPv6)
The remaining part of the address identifies a specific
device within the group.
This portion is unique for each device on the network.
Layer 3 Logical Address
 Devices on the Same Network
When devices are on the
same network the source
and destination will have
the same number in
network
portion of the address.
PC1 – 192.168.1.110
FTP Server – 192.168.1.9
 Role of the Data Link Layer Addresses:
Same IP Network
When devices are on the same Ethernet network the data link
frame will use the actual MAC address of the destination NIC.
MAC addresses are physically embedded into the Ethernet NIC
and are local addressing.
The Source MAC address will be that of the originator on the
link.
The Destination MAC address will always be on the same link
as the source, even if the ultimate destination is remote.
Role of the Data Link Layer Addresses:
Same IP Network
 Devices on a Remote Network

What happens when the
actual (ultimate) destination
is not on the same LAN and is
remote?
What happens when PC1 tries
to reach the Web Server?
Does this impact the network
and data link layers?
 Role of the Network Layer Addresses

When the source and
destination have a
different network portion,
this means they are on
different networks.
PC1 – 192.168.1
Web Server – 172.16.1
 Role of the Data Link Layer Addresses:
Different IP Networks
When the final destination is remote, Layer 3 will provide Layer 2 with
the local default gateway IP address, also known as the router address.
The default gateway (DGW) is the router interface IP address that is part
of this LAN and will be the “door” or “gateway” to all other remote
locations.
All devices on the LAN must be told about this address or their traffic will
be confined to the LAN only.
Once Layer 2 on PC1 forwards to the default gateway (Router), the
router then can start the routing process of getting the information to
actual destination.
 Role of the Data Link Layer Addresses:
Different IP Networks
The data link addressing is local addressing so it will have a source and
destination for each link.
The MAC addressing for the first segment is :
Source – AA-AA-AA-AA-AA-AA (PC1) Sends the frame.
Destination – 11-11-11-11-11-11 (R1-
Default Gateway MAC) Receives the frame.

Note: While the L2 local addressing will change from link to link or hop to
hop, the L3 addressing remains the same.
 Data Link Addresses
Since data link addressing is local addressing, it will have a source and
destination for each segment or hop of the journey to the destination.
The MAC addressing for the first segment is:
Source – (PC1 NIC) sends frame
Destination – (First Router- DGW interface) receives frame
 Data Link Addresses
The MAC addressing for the second hop is:
Source – (First Router- exit interface) sends frame
Destination – (Second Router) receives frame
 Data Link Addresses
Notice that the packet is not modified, but the frame is changed,
therefore the L3 IP addressing does not change from segment to segment
like the L2 MAC addressing.
The L3 addressing remains the same since it is global and the ultimate
destination is still the Web Server.
 Thank You

Reference: Cisco