The OSI model is a 7-layer architecture for data transmission across networks. Each layer has a specific function, from physical transmission of bits at the lowest layer to application-related functions at the highest layer. Together, the 7 layers ensure data is transmitted accurately from one device to another globally through functions like data framing, error checking, routing, and applying logical addresses.
OSI stands for Open Systems Interconnection. It has been developed by ISO – ‘International Organization of Standardization‘, in the year 1984. It is a 7 layer architecture with each layer having specific functionality to perform.
The Open Systems Interconnection (OSI) model began as a reference model, but has since been implemented. It was created by the International Organization for Standardization (ISO) to provide a logical framework for how data communication processes should interact across networks. Standards were created for the computer industry allowing different networks to work together efficiently.ThesisScientist.com
Points Covered
UNIT 1:
1. The Internet Architecture
2. Networking Devices
3. OSI Model
4. TCP/IP Model
5. Topologies
6. Types of Networks with diagrams.
7.
UNIT 2:
1. X.25
2. Frame Relay
3. FDDI
4. Token Ring
5. Bluetooth
6. RFID
7. Asynchronous Transfer Mode (ATM)
UNIT 3:
1. Data Link Layer
2. Error Control
3. Flow Control
4. Types of services provided to the network layer
UNIT 4:
1. Classful IP Addressing
2. Difference between IPV4 and IPV6
3. Piggybacking
4. Methods to improve QoS
5. Subnet, subnet mask, Private IP, Public IP and NAT
6. Congestion Control and how it works in TCP
7. TCP and UDP
8. Explain TCP with its header format
9. Socket
UNIT 5:
1. Application Layer
2. DNS
3. SMTP
4. POP3
5. HTTP
6. URL
7. FTP
8. Basic functions of e-mail system
9. HTTP,FTP Difference
UNIT 6:
1. Network Security Goals
2. Public key Encryption/Decryption
3. Public and Private key Encryption
4. What is a firewall? Mention the types of firewalls
5. Steps followed in creating digital signature
6. Differentiate between digital signature and digital certificate
OSI stands for Open Systems Interconnection. It has been developed by ISO – ‘International Organization of Standardization‘, in the year 1984. It is a 7 layer architecture with each layer having specific functionality to perform.
The Open Systems Interconnection (OSI) model began as a reference model, but has since been implemented. It was created by the International Organization for Standardization (ISO) to provide a logical framework for how data communication processes should interact across networks. Standards were created for the computer industry allowing different networks to work together efficiently.ThesisScientist.com
Points Covered
UNIT 1:
1. The Internet Architecture
2. Networking Devices
3. OSI Model
4. TCP/IP Model
5. Topologies
6. Types of Networks with diagrams.
7.
UNIT 2:
1. X.25
2. Frame Relay
3. FDDI
4. Token Ring
5. Bluetooth
6. RFID
7. Asynchronous Transfer Mode (ATM)
UNIT 3:
1. Data Link Layer
2. Error Control
3. Flow Control
4. Types of services provided to the network layer
UNIT 4:
1. Classful IP Addressing
2. Difference between IPV4 and IPV6
3. Piggybacking
4. Methods to improve QoS
5. Subnet, subnet mask, Private IP, Public IP and NAT
6. Congestion Control and how it works in TCP
7. TCP and UDP
8. Explain TCP with its header format
9. Socket
UNIT 5:
1. Application Layer
2. DNS
3. SMTP
4. POP3
5. HTTP
6. URL
7. FTP
8. Basic functions of e-mail system
9. HTTP,FTP Difference
UNIT 6:
1. Network Security Goals
2. Public key Encryption/Decryption
3. Public and Private key Encryption
4. What is a firewall? Mention the types of firewalls
5. Steps followed in creating digital signature
6. Differentiate between digital signature and digital certificate
The open system interconnection model, better known as the OSI Model, is a network map that was originally developed as a universal standard for creating networks. But instead of serving as a model with agreed-upon protocols that would be used worldwide, the OSI model has become a teaching tool that shows how different tasks within a network should be handled in order to promote error-free data transmission.
This note is about the introduction of the OSI Model & TCP/IP Model. It contains details of the seven layers of the OSI Model which are Application layer, Presentation Layer, Session Layer, Transport Layer, Network Layer, Data Link Layer, Physical Layer
This is a notes about basic introduction of OSI Model & TCP/IP Model. It contain details about the seven layers of the OSI Model which are Application layer, Presentation Layer, Session Layer, Transport Layer, Network Layer, Data Link Layer, Physical Layer
The International Standards Organization (ISO) developed the Open Systems Interconnection (OSI) model. It divides network communication into seven layers. ... Layers 5-7, called the the upper layers, contain application-level data
#imannjeet #mannjeet mn
The Open Systems Interconnection (OSI) model describes seven layers that computer systems use to communicate over a network. It was the first standard model for network communications, adopted by all major computer and telecommunication companies in the early 1980s.
In this PPT, you will be able to get complete, short & sweet slides of OSI Model...
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We’ll kick things off by showcasing the most commonly used event-based triggers, introducing you to various automation workflows like manual triggers, schedules, directory watchers, and more. Plus, see how these elements play out in real scenarios.
Whether you’re tweaking your current setup or building from the ground up, this session will arm you with the tools and insights needed to transform your FME usage into a powerhouse of productivity. Join us to discover effective strategies that simplify complex processes, enhancing your productivity and transforming your data management practices with FME. Let’s turn complexity into clarity and make your workspaces work wonders!
The open system interconnection model, better known as the OSI Model, is a network map that was originally developed as a universal standard for creating networks. But instead of serving as a model with agreed-upon protocols that would be used worldwide, the OSI model has become a teaching tool that shows how different tasks within a network should be handled in order to promote error-free data transmission.
This note is about the introduction of the OSI Model & TCP/IP Model. It contains details of the seven layers of the OSI Model which are Application layer, Presentation Layer, Session Layer, Transport Layer, Network Layer, Data Link Layer, Physical Layer
This is a notes about basic introduction of OSI Model & TCP/IP Model. It contain details about the seven layers of the OSI Model which are Application layer, Presentation Layer, Session Layer, Transport Layer, Network Layer, Data Link Layer, Physical Layer
The International Standards Organization (ISO) developed the Open Systems Interconnection (OSI) model. It divides network communication into seven layers. ... Layers 5-7, called the the upper layers, contain application-level data
#imannjeet #mannjeet mn
The Open Systems Interconnection (OSI) model describes seven layers that computer systems use to communicate over a network. It was the first standard model for network communications, adopted by all major computer and telecommunication companies in the early 1980s.
In this PPT, you will be able to get complete, short & sweet slides of OSI Model...
Developing Distributed High-performance Computing Capabilities of an Open Sci...Globus
COVID-19 had an unprecedented impact on scientific collaboration. The pandemic and its broad response from the scientific community has forged new relationships among public health practitioners, mathematical modelers, and scientific computing specialists, while revealing critical gaps in exploiting advanced computing systems to support urgent decision making. Informed by our team’s work in applying high-performance computing in support of public health decision makers during the COVID-19 pandemic, we present how Globus technologies are enabling the development of an open science platform for robust epidemic analysis, with the goal of collaborative, secure, distributed, on-demand, and fast time-to-solution analyses to support public health.
Essentials of Automations: The Art of Triggers and Actions in FMESafe Software
In this second installment of our Essentials of Automations webinar series, we’ll explore the landscape of triggers and actions, guiding you through the nuances of authoring and adapting workspaces for seamless automations. Gain an understanding of the full spectrum of triggers and actions available in FME, empowering you to enhance your workspaces for efficient automation.
We’ll kick things off by showcasing the most commonly used event-based triggers, introducing you to various automation workflows like manual triggers, schedules, directory watchers, and more. Plus, see how these elements play out in real scenarios.
Whether you’re tweaking your current setup or building from the ground up, this session will arm you with the tools and insights needed to transform your FME usage into a powerhouse of productivity. Join us to discover effective strategies that simplify complex processes, enhancing your productivity and transforming your data management practices with FME. Let’s turn complexity into clarity and make your workspaces work wonders!
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2. OSI stands for Open Systems
Interconnection. It has been
developed by ISO – ‘International
Organization for Standardization‘,
in the year 1984. It is a 7 layer
architecture with each layer having
specific functionality to perform. All
these 7 layers work collaboratively to
transmit the data from one person to
another across the globe.
3. 1. Physical Layer (Layer 1) :
The lowest layer of the OSI reference model is the physical layer. It is
responsible for the actual physical connection between the devices. The
physical layer contains information in the form of bits. It is responsible for
transmitting individual bits from one node to the next. When receiving data,
this layer will get the signal received and convert it into 0s and 1s and
send them to the Data Link layer, which will put the frame back together.
4. The functions of the physical layer are as follows:
1. Bit synchronization: The physical layer provides the synchronization of
the bits by providing a clock. This clock controls both sender and receiver
thus providing synchronization at bit level.
2. Bit rate control: The Physical layer also defines the transmission rate i.e.
the number of bits sent per second.
3. Physical topologies: Physical layer specifies the way in which the
different, devices/nodes are arranged in a network i.e. bus, star, or mesh
topology.
4. Transmission mode: Physical layer also defines the way in which the
data flows between the two connected devices. The various transmission
modes possible are Simplex, half-duplex and full-duplex.
5. 2. Data Link Layer (DLL) (Layer 2) :
The data link layer is responsible for the node-to-node delivery of
the message. The main function of this layer is to make sure data
transfer is error-free from one node to another, over the physical
layer. When a packet arrives in a network, it is the responsibility of
DLL to transmit it to the Host using its MAC address(Media Access
Control).
The packet received from the Network layer is further divided into
frames depending on the frame size of NIC(Network Interface
Card). DLL also encapsulates Sender and Receiver’s MAC address
in the header.
6. The functions of the Data Link layer are :
1. Framing: Framing is a function of the data link layer. It provides a way for a sender to
transmit a set of bits that are meaningful to the receiver. This can be accomplished by
attaching special bit patterns to the beginning and end of the frame.
2. Physical addressing: After creating frames, the Data link layer adds physical addresses
(MAC address) of the sender and/or receiver in the header of each frame.
3. Error control: Data link layer provides the mechanism of error control in which it detects
and retransmits damaged or lost frames.
4. Flow Control: The data rate must be constant on both sides else the data may get
corrupted thus, flow control coordinates the amount of data that can be sent before
receiving acknowledgement.
5. Access control: When a single communication channel is shared by multiple devices, the
MAC sub-layer of the data link layer helps to determine which device has control over the
channel at a given time.
7. 3. Network Layer (Layer 3) :
The network layer works for the transmission of data from one host to the
other located in different networks. It also takes care of packet routing i.e.
selection of the shortest path to transmit the packet, from the number of
routes available. The sender & receiver’s IP addresses are placed in the
header by the network layer.
8. The functions of the Network layer are :
1. Routing: The network layer protocols determine which route is suitable
from source to destination. This function of the network layer is known as
routing.
2. Logical Addressing: In order to identify each device on internetwork
uniquely, the network layer defines an addressing scheme. The sender &
receiver’s IP addresses are placed in the header by the network layer.
Such an address distinguishes each device uniquely and universally.
9. 4. Transport Layer (Layer 4) :
The transport layer provides services to the application layer and takes services from the network
layer. The data in the transport layer is referred to as Segments. It is responsible for the End to
End Delivery of the complete message. The transport layer also provides the acknowledgement of
the successful data transmission and re-transmits the data if an error is found.
At sender’s side: Transport layer receives the formatted data from the upper layers,
performs Segmentation, and also implements Flow & Error control to ensure proper data
transmission. It also adds Source and Destination port numbers in its header and forwards the
segmented data to the Network Layer.
Note: The sender needs to know the port number associated with the receiver’s application.
Generally, this destination port number is configured, either by default or manually. For example,
when a web application makes a request to a web server, it typically uses port number 80,
because this is the default port assigned to web applications. Many applications have default ports
assigned.
At receiver’s side: Transport Layer reads the port number from its header and forwards the Data
which it has received to the respective application. It also performs sequencing and reassembling
of the segmented data.
10. The functions of the transport layer are as follows:
1. Segmentation and Reassembly: This layer accepts the message from
the (session) layer, and breaks the message into smaller units. Each of
the segments produced has a header associated with it. The transport
layer at the destination station reassembles the message.
2. Service Point Addressing: In order to deliver the message to the correct
process, the transport layer header includes a type of address called
service point address or port address. Thus by specifying this address, the
transport layer makes sure that the message is delivered to the correct
process.
11. The services provided by the transport layer :
A. Connection-Oriented Service: It is a three-phase process that
includes
– Connection Establishment
– Data Transfer
– Termination / disconnection
In this type of transmission, the receiving device sends an
acknowledgement, back to the source after a packet or group of packets
is received. This type of transmission is reliable and secure.
B. Connectionless service: It is a one-phase process and includes Data
Transfer. In this type of transmission, the receiver does not acknowledge
receipt of a packet. This approach allows for much faster communication
between devices. Connection-oriented service is more reliable than
connectionless Service.
12. 5. Session Layer (Layer 5) :
This layer is responsible for the establishment of connection,
maintenance of sessions, authentication, and also ensures
security.
13. The functions of the session layer are :
1. Session establishment, maintenance, and termination: The layer
allows the two processes to establish, use and terminate a connection.
2. Synchronization: This layer allows a process to add checkpoints which
are considered synchronization points into the data. These
synchronization points help to identify the error so that the data is re-
synchronized properly, and ends of the messages are not cut
prematurely and data loss is avoided.
3. Dialog Controller: The session layer allows two systems to start
communication with each other in half-duplex or full-duplex
14. 6. Presentation Layer (Layer 6):
The presentation layer is also called the Translation layer. The data from
the application layer is extracted here and manipulated as per the required
format to transmit over the network.
The functions of the presentation layer are :
• Translation: For example, ASCII to EBCDIC.
• Encryption/ Decryption: Data encryption translates the data into another
form or code. The encrypted data is known as the ciphertext and the
decrypted data is known as plain text. A key value is used for encrypting
as well as decrypting data.
• Compression: Reduces the number of bits that need to be transmitted on
the network.
15. 7. Application Layer (Layer 7) :
At the very top of the OSI Reference Model stack of layers, we find the
Application layer which is implemented by the network applications.
These applications produce the data, which has to be transferred over the
network. This layer also serves as a window for the application services to
access the network and for displaying the received information to the
user.
Example: Application – Browsers, Skype Messenger, etc.