Vikas Kumar Jha (India Tata Communications Limited), Bishwajeet Kumar Pandey (India Jain University), Ciro Rodriguez (Peru Universidad Nacional Mayor de San Marcos)
Network Evolution and Applications
Vikas Kumar Jha (India Tata Communications Limited), Bishwajeet Kumar Pandey (India Jain University), Ciro Rodriguez (Peru Universidad Nacional Mayor de San Marcos)
Network Evolution and Applications
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The text gives an understanding and concepts of different types of Internet of things and sensor networks along with respective protocols to the new learners in the field of networking. It further covers foundational information of artificial intelligence for telecommunications.
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The text gives an understanding and concepts of different types of Internet of things and sensor networks along with respective protocols to the new learners in the field of networking. It further covers foundational information of artificial intelligence for telecommunications.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 240
- Erscheinungstermin: 14. November 2022
- Englisch
- Abmessung: 163mm x 241mm x 19mm
- Gewicht: 506g
- ISBN-13: 9781032299563
- ISBN-10: 1032299568
- Artikelnr.: 64687847
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 240
- Erscheinungstermin: 14. November 2022
- Englisch
- Abmessung: 163mm x 241mm x 19mm
- Gewicht: 506g
- ISBN-13: 9781032299563
- ISBN-10: 1032299568
- Artikelnr.: 64687847
- Herstellerkennzeichnung
- Libri GmbH
- Europaallee 1
- 36244 Bad Hersfeld
- 06621 890
Vikas Kumar Jha earned his MTech in computer science engineering from ABV-IIITM, Gwalior, with specialization in advanced networks and a BE degree in electronics and communication engineering from RGPV Bhopal. He did his MTech thesis on Quantum Communication Networks and has five international journal publications under his name. His areas of research include communications, networks, cloud computing, and AI in telecommunication. He has received the following global certifications: Cisco Certifications (CCNA-Routing and Switching and CCNA-Security), Juniper Certification-JNCIA, Amazon Certification-AWS Certified Solution Architect Associate, and Microsoft Certification-Azure Cloud Fundamentals. He has more than 8 years of experience in telecommunication, including with Tata Communications Limited, formerly Videsh Sanchar Nigam Limited. He has also taught undergraduate engineering students as a lecturer in an engineering college for a year. Prof Dr Bishwajeet Pandey earned his PhD in computer science engineering from Gran Sasso Science Institute, L¿Aquila, Italy, under the guidance of Prof Paolo Prinetto, Politecnico DiTorino (World Ranking 13 in Electrical Engineering). He has worked as an assistant professor in the Department of Research, Chitkara University; Junior Research Fellow (JRF) in South Asian University; and lecturer at the Indira Gandhi National Open University. He completed a Master of Computer Applications (MCA) and a Master of Technology (VLSI) from ABVIIITM Gwalior along with R&D project from CDAC-Noida. He is an associate Professor at the Department of Computer Science and Engineering, Jain University, Bangalore, India. He has authored and coauthored 137 papers available on his Scopus Profile: https://www.scopus.com/authid/detail.uri?authorId=57203239026. He has 1400+ citations according to his Google Scholar Profile: https://scholar.google.co.in/citations?user=UZ_8yAMAAAAJ&hl=en. He has experience in the teaching of Innovation and Startup, Computer Network, Digital Logic, Logic Synthesis, and System Verilog. His areas of research interest are green computing, high-performance computing, cyberphysical systems, artificial intelligence, machine learning, and cybersecurity. He is on the board of directors of many startups of his students, e.g., Gyancity Research Consultancy Pvt Ltd. Prof. Dr. Ciro Rodriguez is a professor-researcher at the National Universities Mayor de San Marcos and Federico Villarreal. He completed his PhD in engineering, did advanced studies at the Institute of Theoretical Physics (ICTP), Italy, and in the United States Particle Accelerator School (USPAS),and studied information technology development policy studies, Korea Telecom (KT), South Korea. His areas of research interest include artificial intelligence, health-social welfare, and environment. He holds two patents in the Patent Office INDECOPI in Peru.
Authors' biographies Preface 1. Communication Network at a Glance
Abbreviations Used 1.0 Introduction 1.1 Types of Networks 1.1.1 Based on
spread of network 1.1.2 Based on type of connection 1.1.3 Based on type of
signals 1.2 Network Topology 1.2.1 Bus Topology 1.2.2 Star Topology 1.2.3
Mesh Topology 1.2.4 Ring Topology 1.2.5 Hybrid Topology 1.3 Data
Communication 1.3.1 Use Cases of Data Communication 1.3.2 Different Data
Communication Mode 1.3.3 Components of Data Communication 1.3.4 Cellular or
Mobile Communication 1.3.5 Internet 1.4 International Forums and
Organization 1.4.1 ITU-T 1.4.2 IANA 1.4.3 IETF 1.4.4 3GPP 1.5 Conclusion
References 2. Reference Model and Protocol Suite Abbreviations Used 2.0
Introduction 2.1 Why Standard Protocol Architecture? 2.2 Logistics of
Communication 2.2.1 Protocols 2.2.2 Layers 2.2.3 Service 2.2.4
Client/Server Method 2.2.5 Addressing 2.2.6 Reliability 2.2.7 Flow Control
Mechanism 2.2.8 Connection Oriented - Connection less 2.3 TCP/IP 2.3.1
Layered Architecture 2.3.2 TCP/IP Operation 2.4 OSI 2.4.1 Layered
Architecture 2.4.2 OSI Operation 2.4.3 Comparing TCP/IP and OSI model 2.5
IP Address 2.5.1 IPv4 Address 2.5.2 IPv6 Address 2.6 Conclusion References
3. The First Internet: Project ARPANET Abbreviations Used 3.0 Introduction
3.1 ARPANET 3.1.1 A brief history of ARPANET 3.1.2 Sites of ARPANET 3.1.3
Motivations 3.1.4 ARPANET Topology 3.1.5 ARPANET Network Operation 3.2
Reception, Success and Achievement 3.2.1 Growth of ARPANET 3.2.2 Impact on
Computer Resource & Communication Technology 3.3 Conclusion References 4.
Ethernet Abbreviations Used 4.0 Introduction 4.1 ALOHA 4.1.1 The ALOHA
System - Architecture 4.1.2 ALOHANET 4.1.3 Pure and Slotted: ALOHA
Protocols 4.2 Ethernet History 4.2.1 Experimental Ethernet 4.2.2 Ethernet
Developments in history 4.3 Ethernet Concepts 4.3.1 Physical Layers of
Ethernet 4.3.2 Medium Access Control 4.3.3 Ethernet Frame 4.4 Conclusion
References 5. Journey of Cables: From Coppers to Optical Fiber
Abbreviations used 5.0 Introduction 5.1 History of Telecommunication Cables
5.1.1 POTS 5.1.2 Development of Ethernet 5.1.3 From Analogue to Digital
5.1.4 Transatlantic Cables 5.2 Copper Cables 5.2.1 Twisted Pairs 5.2.2
Coaxial Cables 5.2.3 Hybrid Cables 5.3 Optical Fiber Cables 5.3.1 Single
Mode Fiber 5.3.2 Multi-Mode Fiber 5.4 Conclusion References 6. Wireless
Networks Abbreviations Used 6.0 Introduction 6.1 Wireless Networks &
Communication 6.1.1 Wireless Telegraphy 6.1.2 Mobile Telephone Service -
Pre Cellular 6.1.3 Mobile Communication - Cellular 6.1.4 Wi-Fi 6.1.5 WiMAX
6.1.6 ZigBee 6.1.7 Bluetooth 6.2 Architecture of Wireless Networks 6.2.1
The OSI reference model 6.2.2 Different Types of Wireless Network 6.2.3
Wireless Network Topologies 6.2.4 Wireless Service Modes 6.3 Conclusion
References 7. Circuit Switching & Packet Switching Abbreviations Used 7.0
Introduction 7.1 Switched Network 7.2 Circuit Switching 7.2.1 Manual
Switching 7.2.2 Automatic Switching 7.3 Packet Switching 7.3.1 Datagram
7.3.2 Virtual Circuit 7.4 Conclusion References 8 MPLS Abbreviations Used
8.0 Introduction 8.1 MPLS Background: A Historical view 8.1.1 IP Switching
Technology 8.1.2 TAG Switching 8.1.3 IBM ARIS 8.1.4 MPLS 8.2 Architecture
of MPLS 8.2.1 MPLS Terminologies 8.2.2 MPLS Label Header 8.2.3 MPLS
Operations 8.2.4 Label Operations 8.3 Conclusion References 9. Metro
Ethernet Abbreviations Used 9.0 Introduction 9.1 Metro Ethernet 9.1.1 MEF:
Carrier Ethernet Terminologies 9.1.2 MEF: Carrier Ethernet Services 9.2
Conclusion References 10. Modern Internet Abbreviations Used 10.0
Introduction 10.1 Principles of Modern Internet Architecture 10.1.1
Heterogeneity 10.1.2 Scalability 10.1.3 Simplicity 10.1.4 Robustness and
Adaptability 10.1.5 Loose Coupling 10.1.6 Naming and Addressing 10.1.7
Distributed Architecture 10.2 The Web 10.2.1 Web vs. Internet 10.2.2 Web
2.0 10.3 Conclusion References 11. Software Defined Networking
Abbreviations Used 11.0 Introduction 11.1 Architecture of SDN 11.1.1
Components of SDN 11.1.2 Traffic flow in SDN 11.2 Open Flow Protocol 11.3
Conclusion References 12: Cloud Computing Abbreviations Used 12.0
Introduction 12.1 Background: 12.2 Benefits and limitations of the cloud:
12.2.1 Benefits 12.2.2 Limitations 12.3 Deployment Models: 12.4 Service
models 12.5 Featured Providers 12.6 Architecture 12.7 Cloud Risks: 12.8
Data centers as support for Cloud Computing 12.9 Conclusion References 13:
Internet of Things Abbreviations Used 13.0 Introduction 13.1 IoT world
background 13.1.1 Communication models of IoT 13.1.2 Communications device
to device 13.2 Intercommunication Between Things 13.2.1 Protocols used to
transmit data 13.2.2 Embedded Vision Systems 13.2.3 Webinars On Embedded /
Integrated Vision Systems 13.2.4 Machine Learning 13.2.5 Arduino 13.2.6 The
internet of things as an ally of digital transformation. 13.3 Internet of
Things 2.0: The next step towards industry 4.0 13.4 IoT applications 13.4.1
Business 13.4.2 Vehicle fleets for logistics 13.4.3 IoT applications for
home use 13.4.4 Growth of the number of connected devices 13.4.5 IoT in
agriculture: Smart Farming 13.4.6 Agriculture and Livestock 13.4.7 IoT in
medicine IoMT: Smart Health 13.4.8 IoT in energy management: Smart Energy
13.4.9 IIoT, the industrial internet of things 13.5 Advantages of IoT: 13.6
Limitations of IoT: 13.6.1 Considerations To Integrate IoT Technologies
13.6.2 Challenges And Challenges In Organizations 13.6.3 IoT security 13.7
Future of IoT 13.8 Conclusions References 14. Next Generation IoT and the
World of Sensors Abbreviations Used 14.0 Introduction 14.1 The World of
Sensors 14.2 Functions of the sensors that incorporate the objects with IoT
technology 14.3 The next generation Internet of things 14.4 Opportunities,
Challenges, and Solutions 14.5 Conclusions References 15. Artificial
Intelligence and Networking Abbreviations Used 15.0 Introduction 15.1 What
is AI? 15.1.1 Machine Learning 15.1.2 Neural Network 15.1.3 Deep Learning
15.2 How AI can transform Computer Networks? 15.2.1 Intent-Based Networking
15.2.2 AI in Software Defined Networking 15.2.3 AI in the Telcom Networks
15.2.4 AI in Cyber Security 15.3 Conclusion References
Abbreviations Used 1.0 Introduction 1.1 Types of Networks 1.1.1 Based on
spread of network 1.1.2 Based on type of connection 1.1.3 Based on type of
signals 1.2 Network Topology 1.2.1 Bus Topology 1.2.2 Star Topology 1.2.3
Mesh Topology 1.2.4 Ring Topology 1.2.5 Hybrid Topology 1.3 Data
Communication 1.3.1 Use Cases of Data Communication 1.3.2 Different Data
Communication Mode 1.3.3 Components of Data Communication 1.3.4 Cellular or
Mobile Communication 1.3.5 Internet 1.4 International Forums and
Organization 1.4.1 ITU-T 1.4.2 IANA 1.4.3 IETF 1.4.4 3GPP 1.5 Conclusion
References 2. Reference Model and Protocol Suite Abbreviations Used 2.0
Introduction 2.1 Why Standard Protocol Architecture? 2.2 Logistics of
Communication 2.2.1 Protocols 2.2.2 Layers 2.2.3 Service 2.2.4
Client/Server Method 2.2.5 Addressing 2.2.6 Reliability 2.2.7 Flow Control
Mechanism 2.2.8 Connection Oriented - Connection less 2.3 TCP/IP 2.3.1
Layered Architecture 2.3.2 TCP/IP Operation 2.4 OSI 2.4.1 Layered
Architecture 2.4.2 OSI Operation 2.4.3 Comparing TCP/IP and OSI model 2.5
IP Address 2.5.1 IPv4 Address 2.5.2 IPv6 Address 2.6 Conclusion References
3. The First Internet: Project ARPANET Abbreviations Used 3.0 Introduction
3.1 ARPANET 3.1.1 A brief history of ARPANET 3.1.2 Sites of ARPANET 3.1.3
Motivations 3.1.4 ARPANET Topology 3.1.5 ARPANET Network Operation 3.2
Reception, Success and Achievement 3.2.1 Growth of ARPANET 3.2.2 Impact on
Computer Resource & Communication Technology 3.3 Conclusion References 4.
Ethernet Abbreviations Used 4.0 Introduction 4.1 ALOHA 4.1.1 The ALOHA
System - Architecture 4.1.2 ALOHANET 4.1.3 Pure and Slotted: ALOHA
Protocols 4.2 Ethernet History 4.2.1 Experimental Ethernet 4.2.2 Ethernet
Developments in history 4.3 Ethernet Concepts 4.3.1 Physical Layers of
Ethernet 4.3.2 Medium Access Control 4.3.3 Ethernet Frame 4.4 Conclusion
References 5. Journey of Cables: From Coppers to Optical Fiber
Abbreviations used 5.0 Introduction 5.1 History of Telecommunication Cables
5.1.1 POTS 5.1.2 Development of Ethernet 5.1.3 From Analogue to Digital
5.1.4 Transatlantic Cables 5.2 Copper Cables 5.2.1 Twisted Pairs 5.2.2
Coaxial Cables 5.2.3 Hybrid Cables 5.3 Optical Fiber Cables 5.3.1 Single
Mode Fiber 5.3.2 Multi-Mode Fiber 5.4 Conclusion References 6. Wireless
Networks Abbreviations Used 6.0 Introduction 6.1 Wireless Networks &
Communication 6.1.1 Wireless Telegraphy 6.1.2 Mobile Telephone Service -
Pre Cellular 6.1.3 Mobile Communication - Cellular 6.1.4 Wi-Fi 6.1.5 WiMAX
6.1.6 ZigBee 6.1.7 Bluetooth 6.2 Architecture of Wireless Networks 6.2.1
The OSI reference model 6.2.2 Different Types of Wireless Network 6.2.3
Wireless Network Topologies 6.2.4 Wireless Service Modes 6.3 Conclusion
References 7. Circuit Switching & Packet Switching Abbreviations Used 7.0
Introduction 7.1 Switched Network 7.2 Circuit Switching 7.2.1 Manual
Switching 7.2.2 Automatic Switching 7.3 Packet Switching 7.3.1 Datagram
7.3.2 Virtual Circuit 7.4 Conclusion References 8 MPLS Abbreviations Used
8.0 Introduction 8.1 MPLS Background: A Historical view 8.1.1 IP Switching
Technology 8.1.2 TAG Switching 8.1.3 IBM ARIS 8.1.4 MPLS 8.2 Architecture
of MPLS 8.2.1 MPLS Terminologies 8.2.2 MPLS Label Header 8.2.3 MPLS
Operations 8.2.4 Label Operations 8.3 Conclusion References 9. Metro
Ethernet Abbreviations Used 9.0 Introduction 9.1 Metro Ethernet 9.1.1 MEF:
Carrier Ethernet Terminologies 9.1.2 MEF: Carrier Ethernet Services 9.2
Conclusion References 10. Modern Internet Abbreviations Used 10.0
Introduction 10.1 Principles of Modern Internet Architecture 10.1.1
Heterogeneity 10.1.2 Scalability 10.1.3 Simplicity 10.1.4 Robustness and
Adaptability 10.1.5 Loose Coupling 10.1.6 Naming and Addressing 10.1.7
Distributed Architecture 10.2 The Web 10.2.1 Web vs. Internet 10.2.2 Web
2.0 10.3 Conclusion References 11. Software Defined Networking
Abbreviations Used 11.0 Introduction 11.1 Architecture of SDN 11.1.1
Components of SDN 11.1.2 Traffic flow in SDN 11.2 Open Flow Protocol 11.3
Conclusion References 12: Cloud Computing Abbreviations Used 12.0
Introduction 12.1 Background: 12.2 Benefits and limitations of the cloud:
12.2.1 Benefits 12.2.2 Limitations 12.3 Deployment Models: 12.4 Service
models 12.5 Featured Providers 12.6 Architecture 12.7 Cloud Risks: 12.8
Data centers as support for Cloud Computing 12.9 Conclusion References 13:
Internet of Things Abbreviations Used 13.0 Introduction 13.1 IoT world
background 13.1.1 Communication models of IoT 13.1.2 Communications device
to device 13.2 Intercommunication Between Things 13.2.1 Protocols used to
transmit data 13.2.2 Embedded Vision Systems 13.2.3 Webinars On Embedded /
Integrated Vision Systems 13.2.4 Machine Learning 13.2.5 Arduino 13.2.6 The
internet of things as an ally of digital transformation. 13.3 Internet of
Things 2.0: The next step towards industry 4.0 13.4 IoT applications 13.4.1
Business 13.4.2 Vehicle fleets for logistics 13.4.3 IoT applications for
home use 13.4.4 Growth of the number of connected devices 13.4.5 IoT in
agriculture: Smart Farming 13.4.6 Agriculture and Livestock 13.4.7 IoT in
medicine IoMT: Smart Health 13.4.8 IoT in energy management: Smart Energy
13.4.9 IIoT, the industrial internet of things 13.5 Advantages of IoT: 13.6
Limitations of IoT: 13.6.1 Considerations To Integrate IoT Technologies
13.6.2 Challenges And Challenges In Organizations 13.6.3 IoT security 13.7
Future of IoT 13.8 Conclusions References 14. Next Generation IoT and the
World of Sensors Abbreviations Used 14.0 Introduction 14.1 The World of
Sensors 14.2 Functions of the sensors that incorporate the objects with IoT
technology 14.3 The next generation Internet of things 14.4 Opportunities,
Challenges, and Solutions 14.5 Conclusions References 15. Artificial
Intelligence and Networking Abbreviations Used 15.0 Introduction 15.1 What
is AI? 15.1.1 Machine Learning 15.1.2 Neural Network 15.1.3 Deep Learning
15.2 How AI can transform Computer Networks? 15.2.1 Intent-Based Networking
15.2.2 AI in Software Defined Networking 15.2.3 AI in the Telcom Networks
15.2.4 AI in Cyber Security 15.3 Conclusion References
Authors' biographies Preface 1. Communication Network at a Glance
Abbreviations Used 1.0 Introduction 1.1 Types of Networks 1.1.1 Based on
spread of network 1.1.2 Based on type of connection 1.1.3 Based on type of
signals 1.2 Network Topology 1.2.1 Bus Topology 1.2.2 Star Topology 1.2.3
Mesh Topology 1.2.4 Ring Topology 1.2.5 Hybrid Topology 1.3 Data
Communication 1.3.1 Use Cases of Data Communication 1.3.2 Different Data
Communication Mode 1.3.3 Components of Data Communication 1.3.4 Cellular or
Mobile Communication 1.3.5 Internet 1.4 International Forums and
Organization 1.4.1 ITU-T 1.4.2 IANA 1.4.3 IETF 1.4.4 3GPP 1.5 Conclusion
References 2. Reference Model and Protocol Suite Abbreviations Used 2.0
Introduction 2.1 Why Standard Protocol Architecture? 2.2 Logistics of
Communication 2.2.1 Protocols 2.2.2 Layers 2.2.3 Service 2.2.4
Client/Server Method 2.2.5 Addressing 2.2.6 Reliability 2.2.7 Flow Control
Mechanism 2.2.8 Connection Oriented - Connection less 2.3 TCP/IP 2.3.1
Layered Architecture 2.3.2 TCP/IP Operation 2.4 OSI 2.4.1 Layered
Architecture 2.4.2 OSI Operation 2.4.3 Comparing TCP/IP and OSI model 2.5
IP Address 2.5.1 IPv4 Address 2.5.2 IPv6 Address 2.6 Conclusion References
3. The First Internet: Project ARPANET Abbreviations Used 3.0 Introduction
3.1 ARPANET 3.1.1 A brief history of ARPANET 3.1.2 Sites of ARPANET 3.1.3
Motivations 3.1.4 ARPANET Topology 3.1.5 ARPANET Network Operation 3.2
Reception, Success and Achievement 3.2.1 Growth of ARPANET 3.2.2 Impact on
Computer Resource & Communication Technology 3.3 Conclusion References 4.
Ethernet Abbreviations Used 4.0 Introduction 4.1 ALOHA 4.1.1 The ALOHA
System - Architecture 4.1.2 ALOHANET 4.1.3 Pure and Slotted: ALOHA
Protocols 4.2 Ethernet History 4.2.1 Experimental Ethernet 4.2.2 Ethernet
Developments in history 4.3 Ethernet Concepts 4.3.1 Physical Layers of
Ethernet 4.3.2 Medium Access Control 4.3.3 Ethernet Frame 4.4 Conclusion
References 5. Journey of Cables: From Coppers to Optical Fiber
Abbreviations used 5.0 Introduction 5.1 History of Telecommunication Cables
5.1.1 POTS 5.1.2 Development of Ethernet 5.1.3 From Analogue to Digital
5.1.4 Transatlantic Cables 5.2 Copper Cables 5.2.1 Twisted Pairs 5.2.2
Coaxial Cables 5.2.3 Hybrid Cables 5.3 Optical Fiber Cables 5.3.1 Single
Mode Fiber 5.3.2 Multi-Mode Fiber 5.4 Conclusion References 6. Wireless
Networks Abbreviations Used 6.0 Introduction 6.1 Wireless Networks &
Communication 6.1.1 Wireless Telegraphy 6.1.2 Mobile Telephone Service -
Pre Cellular 6.1.3 Mobile Communication - Cellular 6.1.4 Wi-Fi 6.1.5 WiMAX
6.1.6 ZigBee 6.1.7 Bluetooth 6.2 Architecture of Wireless Networks 6.2.1
The OSI reference model 6.2.2 Different Types of Wireless Network 6.2.3
Wireless Network Topologies 6.2.4 Wireless Service Modes 6.3 Conclusion
References 7. Circuit Switching & Packet Switching Abbreviations Used 7.0
Introduction 7.1 Switched Network 7.2 Circuit Switching 7.2.1 Manual
Switching 7.2.2 Automatic Switching 7.3 Packet Switching 7.3.1 Datagram
7.3.2 Virtual Circuit 7.4 Conclusion References 8 MPLS Abbreviations Used
8.0 Introduction 8.1 MPLS Background: A Historical view 8.1.1 IP Switching
Technology 8.1.2 TAG Switching 8.1.3 IBM ARIS 8.1.4 MPLS 8.2 Architecture
of MPLS 8.2.1 MPLS Terminologies 8.2.2 MPLS Label Header 8.2.3 MPLS
Operations 8.2.4 Label Operations 8.3 Conclusion References 9. Metro
Ethernet Abbreviations Used 9.0 Introduction 9.1 Metro Ethernet 9.1.1 MEF:
Carrier Ethernet Terminologies 9.1.2 MEF: Carrier Ethernet Services 9.2
Conclusion References 10. Modern Internet Abbreviations Used 10.0
Introduction 10.1 Principles of Modern Internet Architecture 10.1.1
Heterogeneity 10.1.2 Scalability 10.1.3 Simplicity 10.1.4 Robustness and
Adaptability 10.1.5 Loose Coupling 10.1.6 Naming and Addressing 10.1.7
Distributed Architecture 10.2 The Web 10.2.1 Web vs. Internet 10.2.2 Web
2.0 10.3 Conclusion References 11. Software Defined Networking
Abbreviations Used 11.0 Introduction 11.1 Architecture of SDN 11.1.1
Components of SDN 11.1.2 Traffic flow in SDN 11.2 Open Flow Protocol 11.3
Conclusion References 12: Cloud Computing Abbreviations Used 12.0
Introduction 12.1 Background: 12.2 Benefits and limitations of the cloud:
12.2.1 Benefits 12.2.2 Limitations 12.3 Deployment Models: 12.4 Service
models 12.5 Featured Providers 12.6 Architecture 12.7 Cloud Risks: 12.8
Data centers as support for Cloud Computing 12.9 Conclusion References 13:
Internet of Things Abbreviations Used 13.0 Introduction 13.1 IoT world
background 13.1.1 Communication models of IoT 13.1.2 Communications device
to device 13.2 Intercommunication Between Things 13.2.1 Protocols used to
transmit data 13.2.2 Embedded Vision Systems 13.2.3 Webinars On Embedded /
Integrated Vision Systems 13.2.4 Machine Learning 13.2.5 Arduino 13.2.6 The
internet of things as an ally of digital transformation. 13.3 Internet of
Things 2.0: The next step towards industry 4.0 13.4 IoT applications 13.4.1
Business 13.4.2 Vehicle fleets for logistics 13.4.3 IoT applications for
home use 13.4.4 Growth of the number of connected devices 13.4.5 IoT in
agriculture: Smart Farming 13.4.6 Agriculture and Livestock 13.4.7 IoT in
medicine IoMT: Smart Health 13.4.8 IoT in energy management: Smart Energy
13.4.9 IIoT, the industrial internet of things 13.5 Advantages of IoT: 13.6
Limitations of IoT: 13.6.1 Considerations To Integrate IoT Technologies
13.6.2 Challenges And Challenges In Organizations 13.6.3 IoT security 13.7
Future of IoT 13.8 Conclusions References 14. Next Generation IoT and the
World of Sensors Abbreviations Used 14.0 Introduction 14.1 The World of
Sensors 14.2 Functions of the sensors that incorporate the objects with IoT
technology 14.3 The next generation Internet of things 14.4 Opportunities,
Challenges, and Solutions 14.5 Conclusions References 15. Artificial
Intelligence and Networking Abbreviations Used 15.0 Introduction 15.1 What
is AI? 15.1.1 Machine Learning 15.1.2 Neural Network 15.1.3 Deep Learning
15.2 How AI can transform Computer Networks? 15.2.1 Intent-Based Networking
15.2.2 AI in Software Defined Networking 15.2.3 AI in the Telcom Networks
15.2.4 AI in Cyber Security 15.3 Conclusion References
Abbreviations Used 1.0 Introduction 1.1 Types of Networks 1.1.1 Based on
spread of network 1.1.2 Based on type of connection 1.1.3 Based on type of
signals 1.2 Network Topology 1.2.1 Bus Topology 1.2.2 Star Topology 1.2.3
Mesh Topology 1.2.4 Ring Topology 1.2.5 Hybrid Topology 1.3 Data
Communication 1.3.1 Use Cases of Data Communication 1.3.2 Different Data
Communication Mode 1.3.3 Components of Data Communication 1.3.4 Cellular or
Mobile Communication 1.3.5 Internet 1.4 International Forums and
Organization 1.4.1 ITU-T 1.4.2 IANA 1.4.3 IETF 1.4.4 3GPP 1.5 Conclusion
References 2. Reference Model and Protocol Suite Abbreviations Used 2.0
Introduction 2.1 Why Standard Protocol Architecture? 2.2 Logistics of
Communication 2.2.1 Protocols 2.2.2 Layers 2.2.3 Service 2.2.4
Client/Server Method 2.2.5 Addressing 2.2.6 Reliability 2.2.7 Flow Control
Mechanism 2.2.8 Connection Oriented - Connection less 2.3 TCP/IP 2.3.1
Layered Architecture 2.3.2 TCP/IP Operation 2.4 OSI 2.4.1 Layered
Architecture 2.4.2 OSI Operation 2.4.3 Comparing TCP/IP and OSI model 2.5
IP Address 2.5.1 IPv4 Address 2.5.2 IPv6 Address 2.6 Conclusion References
3. The First Internet: Project ARPANET Abbreviations Used 3.0 Introduction
3.1 ARPANET 3.1.1 A brief history of ARPANET 3.1.2 Sites of ARPANET 3.1.3
Motivations 3.1.4 ARPANET Topology 3.1.5 ARPANET Network Operation 3.2
Reception, Success and Achievement 3.2.1 Growth of ARPANET 3.2.2 Impact on
Computer Resource & Communication Technology 3.3 Conclusion References 4.
Ethernet Abbreviations Used 4.0 Introduction 4.1 ALOHA 4.1.1 The ALOHA
System - Architecture 4.1.2 ALOHANET 4.1.3 Pure and Slotted: ALOHA
Protocols 4.2 Ethernet History 4.2.1 Experimental Ethernet 4.2.2 Ethernet
Developments in history 4.3 Ethernet Concepts 4.3.1 Physical Layers of
Ethernet 4.3.2 Medium Access Control 4.3.3 Ethernet Frame 4.4 Conclusion
References 5. Journey of Cables: From Coppers to Optical Fiber
Abbreviations used 5.0 Introduction 5.1 History of Telecommunication Cables
5.1.1 POTS 5.1.2 Development of Ethernet 5.1.3 From Analogue to Digital
5.1.4 Transatlantic Cables 5.2 Copper Cables 5.2.1 Twisted Pairs 5.2.2
Coaxial Cables 5.2.3 Hybrid Cables 5.3 Optical Fiber Cables 5.3.1 Single
Mode Fiber 5.3.2 Multi-Mode Fiber 5.4 Conclusion References 6. Wireless
Networks Abbreviations Used 6.0 Introduction 6.1 Wireless Networks &
Communication 6.1.1 Wireless Telegraphy 6.1.2 Mobile Telephone Service -
Pre Cellular 6.1.3 Mobile Communication - Cellular 6.1.4 Wi-Fi 6.1.5 WiMAX
6.1.6 ZigBee 6.1.7 Bluetooth 6.2 Architecture of Wireless Networks 6.2.1
The OSI reference model 6.2.2 Different Types of Wireless Network 6.2.3
Wireless Network Topologies 6.2.4 Wireless Service Modes 6.3 Conclusion
References 7. Circuit Switching & Packet Switching Abbreviations Used 7.0
Introduction 7.1 Switched Network 7.2 Circuit Switching 7.2.1 Manual
Switching 7.2.2 Automatic Switching 7.3 Packet Switching 7.3.1 Datagram
7.3.2 Virtual Circuit 7.4 Conclusion References 8 MPLS Abbreviations Used
8.0 Introduction 8.1 MPLS Background: A Historical view 8.1.1 IP Switching
Technology 8.1.2 TAG Switching 8.1.3 IBM ARIS 8.1.4 MPLS 8.2 Architecture
of MPLS 8.2.1 MPLS Terminologies 8.2.2 MPLS Label Header 8.2.3 MPLS
Operations 8.2.4 Label Operations 8.3 Conclusion References 9. Metro
Ethernet Abbreviations Used 9.0 Introduction 9.1 Metro Ethernet 9.1.1 MEF:
Carrier Ethernet Terminologies 9.1.2 MEF: Carrier Ethernet Services 9.2
Conclusion References 10. Modern Internet Abbreviations Used 10.0
Introduction 10.1 Principles of Modern Internet Architecture 10.1.1
Heterogeneity 10.1.2 Scalability 10.1.3 Simplicity 10.1.4 Robustness and
Adaptability 10.1.5 Loose Coupling 10.1.6 Naming and Addressing 10.1.7
Distributed Architecture 10.2 The Web 10.2.1 Web vs. Internet 10.2.2 Web
2.0 10.3 Conclusion References 11. Software Defined Networking
Abbreviations Used 11.0 Introduction 11.1 Architecture of SDN 11.1.1
Components of SDN 11.1.2 Traffic flow in SDN 11.2 Open Flow Protocol 11.3
Conclusion References 12: Cloud Computing Abbreviations Used 12.0
Introduction 12.1 Background: 12.2 Benefits and limitations of the cloud:
12.2.1 Benefits 12.2.2 Limitations 12.3 Deployment Models: 12.4 Service
models 12.5 Featured Providers 12.6 Architecture 12.7 Cloud Risks: 12.8
Data centers as support for Cloud Computing 12.9 Conclusion References 13:
Internet of Things Abbreviations Used 13.0 Introduction 13.1 IoT world
background 13.1.1 Communication models of IoT 13.1.2 Communications device
to device 13.2 Intercommunication Between Things 13.2.1 Protocols used to
transmit data 13.2.2 Embedded Vision Systems 13.2.3 Webinars On Embedded /
Integrated Vision Systems 13.2.4 Machine Learning 13.2.5 Arduino 13.2.6 The
internet of things as an ally of digital transformation. 13.3 Internet of
Things 2.0: The next step towards industry 4.0 13.4 IoT applications 13.4.1
Business 13.4.2 Vehicle fleets for logistics 13.4.3 IoT applications for
home use 13.4.4 Growth of the number of connected devices 13.4.5 IoT in
agriculture: Smart Farming 13.4.6 Agriculture and Livestock 13.4.7 IoT in
medicine IoMT: Smart Health 13.4.8 IoT in energy management: Smart Energy
13.4.9 IIoT, the industrial internet of things 13.5 Advantages of IoT: 13.6
Limitations of IoT: 13.6.1 Considerations To Integrate IoT Technologies
13.6.2 Challenges And Challenges In Organizations 13.6.3 IoT security 13.7
Future of IoT 13.8 Conclusions References 14. Next Generation IoT and the
World of Sensors Abbreviations Used 14.0 Introduction 14.1 The World of
Sensors 14.2 Functions of the sensors that incorporate the objects with IoT
technology 14.3 The next generation Internet of things 14.4 Opportunities,
Challenges, and Solutions 14.5 Conclusions References 15. Artificial
Intelligence and Networking Abbreviations Used 15.0 Introduction 15.1 What
is AI? 15.1.1 Machine Learning 15.1.2 Neural Network 15.1.3 Deep Learning
15.2 How AI can transform Computer Networks? 15.2.1 Intent-Based Networking
15.2.2 AI in Software Defined Networking 15.2.3 AI in the Telcom Networks
15.2.4 AI in Cyber Security 15.3 Conclusion References