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A thesis Submitted to
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| bet | 3/14 | | Sana | 09.09.2023 | | Hajmi | 2.64 Mb. | | #80939 |
Bog'liq asosiyyy diplom uchun (1) MTA Majmua(2021), 1, 4-Karno kartadan foydalanib mantiqiy ifodalarni minimallash, Kalendar reja algoritm, Ishchi dastur(Dasturlash I) 24.11.2021, 1 -amaliyot, 4-Lab, Yurtimiz mustaqillikga erishishidan oldin milliy urf odat, 7-8-mavzuDT larni sertifikatlashtirish, Axborotlarni izlash va ajratib olish fanidan mustaqil ish Mavzu, Abdulla Oripov O\'zbekiston (qasida), 2 lab Yarashov Diyorbek, TATU NF Hemis axborot tizimi, Algo 1-299, prezentatsiya
Figure Page
Figure 1.1. Iot Applications 5
Figure 2.1. Cisco Packet Tracer Interface 6
Figure 2.2. Physical View of Isp Router 7
Figure 2.3. Cisco Packet Tracer Command Line Interface Tab 9
Figure 2.4. Cisco Packet Tracer Config Tab 9
Figure 3.1. Cisco Packet Tracer Smart devices 11
Figure 3.2. Smart home Application 13
Figure 3.3. Methodology of the Design 15
Figure 3.4. Flow Diagram 16
Figure 3.5. Smart home with Cisco Packet Tracer 17
Figure 3.6. Home Gateway 18
Figure 3.7. Smart Ligth Connected to the Home Gateway 19
Figure 3.8. Physical View Of ISP Router 20
Figure 3.9. Ip Address assignment for Iot Server 22
Figure 3.10. Connecting Iot Devices to Iot Server 22
Figure 3.11. Domain Name Configuration 23
Figure 3.12. IP Address Assignment for DNS Server 23
Figure 3.13. WAN Configuration 24
Figure 3.14. Central Office Server 25
Figure 3.15. Old Car Specificaions 26
Figure 3.16. Smart Car Specifications 26
Figure 3.17. Smart Phone Physical View 27
Figure 3.18. Smart Phone Connection to the Cell Tower 28
Figure 3.19. Registration Server login 29
Figure 3.20. IOT Devices Status 29
LIST OF TABLE
Table Page
Table 1.1. Cisco Prediction of Connected Devices 3
Table 2.1. Protocol Supported by Cisco Packet Tracer 10
Table 3.1. Devices Used for the Simulation 13
ABBREVIATIONS
3GPP
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3rd Generation Partnership Project
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API
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Application Programming Interface
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APN
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Access Point Name
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ARPANET
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Advanced Research Project Agency Network
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CLI
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Command Line Interface
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DHCP
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Dynamic Host Configuration Protocol
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DNS
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Domain Name System
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GUI
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Graphical User Interface
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IaaS
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Infrastructure as a Service
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IoE
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Internet of Everything
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IoT
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Internet of Things
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ISP
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Internet Service Provider
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LAN
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Local Area Network
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NetAcad
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Cisco Networking Academy
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RFID
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Radio Frequency Identification
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RIP
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Routing Information Protocol
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SaaS
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Software as a Service
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POP3
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Post Office Protocol version 3
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Telnet
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TELecommunications NETwork
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SSH
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Secure Socket Shell
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DSL
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Digital Subscriber Line
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FTP
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File Transfer Protocol
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SMTP
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Simple Mail Transfer Protocol
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HTTP
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Hypertext Transfer Protocol
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TFTP
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Trivial File Transfer Protocol
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AAA
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Authentication, Authorization, and Accounting
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NTP
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Network Time Protocol
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SNMP
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Simple Network Management Protocol
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VOIP
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Voice-Over-IP
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SCCP
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Signaling Connection Control Part
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ISR
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International Standard Recording
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TCP
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Transmission Control Protocol
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UDP
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User Datagram Protocol
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BGP
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Border Gateway Protocol(TCP/IP)
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ICMP
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Internet Control Message Protocol
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IP
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Internet Protocol
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ARP
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Address Resolution Protocol
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NAT
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Network address translation
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GRE
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Generic Routing Encapsulation
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IPSec
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IP Security
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VPN
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Virtual Private Network
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HDLC
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High-level Data Link Control
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PPP
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Point to Point Protocol
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STP
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Spanning-Tree Protocol
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PPPoE
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PPP Over Ethernet
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DTP
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Data Transfer Process
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VTP
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VLAN Trunking Protocol
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QoS
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Quality Of Service
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CDP
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CRL Distribution Point [Microsoft
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WEP
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Wired Equivalent Privacy
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SLARP
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Serial Line Address Resolution Protocol
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WAN
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Wide-Area Network
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WAP
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Wireless Access Protocol
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TCP/IP
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Transmission Control Protocol/Internet Protocol
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EAP
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Extensible Authentication Protocol [Microsoft]
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PKT
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Packet Tracer file extension
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PSK
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Phase Shift Keying
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SSID
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Service set identifier
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CHAPTER 1
INTRODUCTION
Introduction
Computer networks are considered to be very complex and difficult to implement and operate. Moreover, with IoT (internet of things) technology, where we connect any sort of devices on internet such as refrigerator, air conditioner, fan etc. this complexity becomes even higher. Many documents show that there are actually 13 billion IoT (internet of things) devices connected to the internet, and that there is a possibility that this number will go up to 30 billion in the next three years. [1]
This complexity of the network will give students some though time for learning and understanding how this technology work. Therefore, it is very important to provide a network learning and practical tools, where student can simulate or build and manage the systems for better understanding of the philosophy behind networks. [2]
Network simulation tools are used for testing how the network will work before being physically installed. There are many tools for network simulation: NS-2, TOSSIM, OMNeT++, J-Sim, Avrora, and the common one Cisco Packet Tracer. [9]
Cisco packet tracer is a powerful software created by Cisco Company for simulating virtual networks, especially wireless networks. Cisco packet tracer gives an environment where devices look what they do in reality, and this is very important for users especially students. They can monitor and interact with different wireless and IoT devices in virtual environment before working in real time. [3]
Working with simulation tools to learn how networks work give us both time and materials advantages and help decreasing the costs in education.
This thesis is organized as follows: the first part of the thesis is the introduction, the second part is focused on cisco packet tracer simulation tools, the third part of the thesis is about the implementation of smart home with cisco packet tracer, and the last part is conclusion and future research
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