CONTENTS - SIM University
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1 SIM UNIVERSITY SCHOOL OF SCIENCE AND TECHNOLOGY COMPUTER NETWORK DESIGN OF A PRIMARY SCHOOL STUDENT : GOH SI YUAN (H0805960) SUPERVISOR : DR YANG ZHIZONG PROJECT CODE : JUL2010/ICT/059 A project report submitted to SIM University in partial fulfilment of the requirements for the degree of Bachelor of Information Technology and Business May 2011 ICT499 CAPSTONE PROJECT REPORT 2 TABLE OF CONTENTS Page ABSTRACT 04 ACKNOWLEDGEMENT 05 CHAPTER ONE INTRODUCTION 1.1 Background and Motivation 1.2 Objectives 1.3 Scope 1.4 Layout of the Project report 06 CHAPTER TWO REQUIREMENTS 2.1 Stakeholder requirements 2.2 Solution requirements 2.3 System requirements 2.4 Infrastructure requirements 15 CHAPTER THREE FEATURES 3.1 Network features 3.2 Servers features 3.3 Facilities features 18 CHAPTER FOUR DESIGN 4.1 Network configuration 4.2 Network type 4.3 IP addressing scheme design 4.4 Network diagram design CHAPTER FIVE ICT499 CAPSTONE PROJECT REPORT 25 3 PROJECT MANAGEMENT 5.1 Methodology 5.2 Schedule 5.3 Risk assessment 36 CHAPTER SIX INVESTIGATIONS AND EXPERIMENTS 6.1 Comparison of physical network topologies 6.2 Comparison of logical network topologies 6.3 Hardware 6.4 Software 6.5 Evaluation 49 CHAPTER SEVEN SIMULATION 7.1 Network simulation model 7.2 Network simulation features 7.3 Network configuration 7.4 Virtual Local Area Network 7.5 IP addressing scheme 7.6 Testing 7.7 Evaluation 68 CHAPTER EIGHT CONCLUSIONS AND RECOMMENDATIONS 84 CHAPTER NINE REFLECTION REFERENCES APPENDIX A APPENDIX B APPENDIX C APPENDIX D ICT499 CAPSTONE PROJECT REPORT 86 4 Abstract This project investigates the design considerations, requirements and network features for a typical primary school's computer network with the development of a simulated computer network. SDLC or Systems Development Life Cycle is adopted as the methodology, enabling this project to be developed in a structured manner. The purpose of this project is to propose a optimized computer network which meets the design considerations, requirements and features for a typical primary school in Singapore. In this project, the design considerations, requirements and features of the proposed network are investigated. A full functional simulation of a primary school computer network was generated and evaluation of the network are carry out. This project exploit the approach in designing a computer network by evaluating the network first through computer simulation before the implementation. Compare to traditional computer network design process, this approach enhance the traditional network design process which proof to be advisable and more cost efficiency. The comparison of physical and logical network topologies illustrated that Server/Client network configuration, Star physical network topology and Ethernet logical network topology should be employed in the project which will provide a variety of features. Lastly in the project, a primary school's computer network is presented in a simulation environment to be display graphically for demonstration of results. ICT499 CAPSTONE PROJECT REPORT 5 Acknowledgements Throughout the development of this capstone project, I wish to express my thanks and utmost gratitude to those have made this project possible. Among those whom I wish to thank is my project supervisor Dr Yang ZhiZong, for his valuable advice and diligence attention towards this capstone project completion. Next is my friend Mr Ho Yeo Sin for his guidance in various aspects of the simulation in this project. I also will like to use this opportunity to thank my family who supported and encouraged me throughout my three and a half years of study in Unisim. ICT499 CAPSTONE PROJECT REPORT 6 Chapter 1 - Introduction 1.1 Background and Motivation Many of our schools today were built over the last 20-30 years. In 1999, Ministry of Education (MOE) initiated a major programme for rebuilding and improving existing schools (PRIME). It aims to redevelop the schools to the latest standard and ensure that all students have access to facilities that can support a wide range of educational programmes. New and upgraded facilities will include computer laboratories, media resource libraries, IT learning resource rooms, pastoral care rooms and health and fitness rooms. Teachers and students can also look forward to bigger classrooms and staffrooms, and more interaction areas ("prime", 2011). In today society, computer networks are the core of modern communication. It is a collection of computers and devices interconnected by communications channels that facilitate communications among users and allows users to share resources ("Computer network", 2011). A computer network would allows the school to share and exchange data, facilitate communications, sharing of hardware & software and information presentation. Today, majority of the primary school are still operating without a computer network that connect the school facilities together. But the implementation of networking the school after the "PRIME" programme is completed will be inevitable. At the core of the "PRIME" programme, there must be a optimized computer network design that can support and exploit the functionality of these new and upgraded facilities. Traditional computer network design process encompassing topological design, network-synthesis, and network-realization, and is aimed at ensuring that a new computer network meets the needs of the user ("Network planning and design", 2011) but it simply presume that the performance will meets the ICT499 CAPSTONE PROJECT REPORT 7 requirements lay down by the user and no problems would occur because there are no means to measure the realistic performance of the network and mechanism to identify the problems until implementation is completed. As a result, a new computer network design approach would be employed in this project so as to evaluate the differences with the traditional approach. ICT499 CAPSTONE PROJECT REPORT 8 1.2 Objectives This project is to develop a simulation of a computer network design using computer software to investigate design considerations and requirements for a typical primary school in Singapore. This approach enable a full functional simulation for a primary school computer network that meets the requirements in accessibility, scalability and security to be generated and evaluation of the network performance to be carry out. To investigate the design considerations, requirements and features of a primary school To develop the optimized computer network design in a simulated environment To develop a graphical demonstration for the presentation of the project result To investigate the different network topologies, configurations and technologies that may significantly affect the network design To present an optimized computer network design for a primary school. To present the evaluation of network design process selected against the traditional network design process This project offer an alternative approach to design a computer network which evaluate its performance first by using computer simulation before implementing the network design in real life. Traditional computer network design process encompassing topological design, network-synthesis, and network-realization, and is aimed at ensuring that a new network meets the needs of the user ("Network planning and design", 2011) but it only able to presume that the performance will meets the requirements lay down by the user because there are no means to measure the realistic performance of the network until implementation is finished. ICT499 CAPSTONE PROJECT REPORT 9 With this project, performance of the network is evaluated first to ensure it meets the requirements before implementation in real life. This project proof to be worthwhile and important because The project enables design of a computer network to be achieved with low cost and less pressure from environmental factors. The project makes work more effective as the consequences of the computer simulation's actions or changes can be seen immediately. The project enables a wide range of objectives required for the computer network design to be accomplished in a short period of time. The project enables the computer network design's performance to be evaluated through analyzing the data recorded. The project ensures that the computer network design meets the requirements of the user before implementation. The project enables the computer network design to be displayed graphically to user for demonstration of results. Hence, the second main objective of this project is to enhance the process of current computer network design by implementing the design in a simulated software environment first so as to develop a computer network design that can meets the requirements of the user more closely. ICT499 CAPSTONE PROJECT REPORT 10 1.3 Scope Project Objective: Investigate the design considerations, requirements and features required for a typical primary school's computer network. Develop a functional simulation of the optimized computer network using Cisco Packet Tracer 5.3 software. Evaluate the computer network design process employed in this project against the traditional network design process. Deliverables: Planning Phase 1. Project objectives & problems 2. Project proposal Analysis Phase 1. Feasibility studies results 2. Project interim report Design Phase 1. Project network topology 2. Project IP addressing scheme 3. Project network diagram 4. Project physical network diagram Implementation Phase ICT499 CAPSTONE PROJECT REPORT 11 1. Project computer network simulation Evaluation Phase 1. Requirements verification results 2. Simulation testing results 3. Network performance evaluation results Project report writing Phase 1. Project report 2. Project poster 3. Project presentation slides Milestones: Completion of planning phase Submission of project proposal Completion of analysis phase Submission of project interim report Completion of design phase Completion of implementation phase Completion of evaluation phase Submission of project report, poster & presentation slides ICT499 CAPSTONE PROJECT REPORT 12 1.4 Layout of the Project report This project report consists of nine chapters. This section of the report provide an overview of each chapter in this project report. Each chapter is organized in a structured manner in the report as below: Chapter 1 - Introduction This chapter describe the background and motivation of this project with project objectives and problems defined. Scope of the project provide the details on the main project objectives, deliverables in each phase of the project and each milestone in this project. Layout of the project report is included to give the overview of each chapter in this report. Chapter 2 - Requirements This chapter define the different types of requirements identified in this project. Requirements identified are stakeholder requirements, solution requirements, system requirements and infrastructure requirements. Identifying the requirements allow the verifying of requirements at the end of the project and make available a checklist of requirements that ensure at the end of the project the requirements are meets. Chapter 3 - Features This chapter define the different types of features identified in this project. Features identified are network features, server features and facilities features. This chapter investigate the different features and the advantages and disadvantages of having it in the project. Chapter 4 - Design ICT499 CAPSTONE PROJECT REPORT 13 This chapter investigate different network topologies available in the designing of the project computer network. It describe the developing of the IP addressing scheme and designing of the IP addressing scheme applied in this project. This chapter further explain the designing of network diagram in this project and the project network design diagram are illustrated. Chapter 5 - Project management This chapter define the methodology, SDLC or Systems Development Life Cycle that is applied in this project. Project's schedule developed using Microsoft Office Project which includes the project activity list and project gnatt chart are illustrated to offer an overview of the project schedule planned. A project risk assessment is been done so as to identify the problems that may occur and establish a risk response to deal with the problems. Chapter 6 - Investigation and Experiments This chapter consists of the comparison results of the physical and logical network topologies which define the advantages and disadvantages of each physical and logical topologies and its suitability in this project.The investigation results of the equipments needed for the implementation and the software suitable for the simulation of the computer network will be included in this chapter. And an evaluation of the investigation and experiments taken in this project. Chapter 7 - Simulation This chapter discuss on the simulation model developed for the computer network and the features available in this simulation model. It will also show the process involved and network configuration of this simulated computer network. Detail of the virtual local area network(Vlan) and IP addressing ICT499 CAPSTONE PROJECT REPORT 14 scheme in this model will be illustrated. This chapter will also present the detail on the testing results of the simulation model and the evaluation results. Chapter 8 - Conclusions and recommendations This chapter will conclude the project results obtained and the recommendation for the improvement and enhancement of a typical primary school computer network. Chapter 9 - Reflection Chapter 9 will review the entire period involve in the development of this capstone project so as to provide an account based on the report, project's schedule, meeting logs and the discussion with my project supervisor, and how the project can be done better and the development of the skills needed in this project. ICT499 CAPSTONE PROJECT REPORT 15 Chapter 2 - Requirements 2.1 Stakeholder requirements Stakeholder requirements are statements of the needs of a particular stakeholder or class of stakeholders. They describe the needs that a given stakeholder has and how that stakeholder will interact with a solution (IIL 2011, Pg6-11). The stakeholder register, Table 2.1 is used to identify those people and organizations impacted by this project, stakeholder register are illustrated under Appendix A in this report. The stakeholder requirements documentation, Table 2.2 includes requirements ID, requirement description, and stakeholders associated with requirements. This documentation assists in making trade-off decisions among requirements at the same time enable the verification of requirements at the evaluation phase, and in managing stakeholder expectations (IIL 2011, Pg6-11). Stakeholder Requirements Documentation are illustrated under Appendix A in this report. 2.2 Solution requirements Solution requirements describe the characteristics of a solution that meet stakeholder requirements. They are divided into sub-categories of functional and non-functional requirements. Functional requirements describe the behavior and information that the solution will manage. They describe capabilities the system will be able to perform in terms of behaviors or operations (IIL 2011, Pg6-11). The functional requirements documentation, Table 2.3 includes requirements ID and the requirement description. Functional Requirements Documentation illustrated under Appendix A in this report ICT499 CAPSTONE PROJECT REPORT are 16 Non-functional requirements capture conditions that do not directly relate to the behavior or functionality of the solution, but rather describe environmental conditions under which the solution must remain effective or qualities that the system have (IIL 2011, Pg6-11). These can include requirements related to capacity, speed, security, availability and reliability. The non-functional requirements documentation, Table 2.4 includes requirements ID and the requirement description. Non-Functional Requirements Documentation are illustrated under Appendix A in this report 2.3 System requirements System requirements describe the requirements about the hardware and software required to run or support the solution (IIL 2011, Pg6-11). These can include requirements related to conversion, maintenance & support, reusability, archiving/retention and processing. The system requirements documentation, Table 2.5 includes requirements ID and the requirement description. System Requirements Documentation are illustrated under Appendix A in this report. 2.4 Infrastructure requirements Infrastructure requirements specify any requirements that ensure the new solution will connect properly to external components (IIL 2011, Pg6-11). The infrastructure requirements documentation, Table 2.6 includes requirements ID and the requirement description. Infrastructure Requirements Documentation are illustrated under Appendix A in this report. Before the beginning of designing the computer network design, one should need is a complete assessment of expected functionality. Identifying the tasks that needed to perform more efficient through the utilize of computer network, the applications needed to support and all different types of requirements. Only after identifying all the stakeholders and the requirements ensure that the ICT499 CAPSTONE PROJECT REPORT 17 computer network that is design would fit the needs and requirements of the users. ICT499 CAPSTONE PROJECT REPORT 18 Chapter 3 - Features 3.1 Network features Speed - Networks provide a very rapid method for sharing and transferring files. Without a network, files are shared by copying them to portable media, then carrying or sending from one computer to another. This method of transferring files in this manner is very time-consuming. Cost - The network version of most software programs are available at considerable savings when compared to buying individually licensed copies. Besides monetary savings, sharing a program on a network allows for easier upgrading of the program. The changes have to be done only once, on the file server, instead of on all the individual workstations. Centralized Software Management - One of the greatest benefits of installing a network at a school is the fact that all of the software can be loaded on one computer (the file server). This eliminates that need to spend time and energy installing updates and tracking files on independent computers throughout the building. Resource Sharing - Sharing resources is another area in which a network exceeds stand-alone computers. Most schools cannot afford enough laser printers, fax machines, modems, scanners, projector and bluray players for each computer. However, if these or similar peripherals are added to a network, they can be shared by many users. Flexible Access - School networks allow students to access their files from computers throughout the school. Students can begin an assignment in their classroom, save part of it on a public access area of the network, ICT499 CAPSTONE PROJECT REPORT 19 then go to the media centre after school to finish their work. Students can also work cooperatively through the network. Security - Files and programs on a network can be designated as "copy inhibit," so that you do not have to worry about illegal copying of programs. Also, passwords can be established for specific directories to restrict access to authorized users. ("Introduction", 2011) Wireless Technology - Wireless technology enable network to connect users who travel from location to location and also network a LAN segment that must frequently change locations. This technology would be of assistance to overcome situations where normal cabling is difficult or financially impractical. User-level Security - It provide access control to a file, printer or other network resources based on user login. It provides greater protection than share-level security, because users are identified individually or within a group. User-level permissions are stored in a central server and managed by the network IT administrator. Cisco Network Features - Cisco network equipments would provide the network with the following Ease-of-Use & Ease-of-Deployment, performance, management options, manageability, availability, VLAN, security, QoS & CoS, Power-over-Ethernet and monitoring features. This features would further enhance the computer network capability. 3.2 Servers features Proxy server - A server that acts an intermediary for requests from clients seeking resources or services like a file, connection, web page ICT499 CAPSTONE PROJECT REPORT 20 from other servers. This server would act as the control when student access the internet to prevent them from accessing undesired sites. But this server would required an individual with related knowledge to configure, updating and maintaining it. DHCP server - DHCP allows a computer to be configured automatically, eliminating the need for intervention by a network administrator. It also provides a central database for keeping track of computers that have been connected to the network. ("DHCP", 2011) But this server would required an individual with related knowledge to configure, updating and maintaining it. File server - A server attached to a network that has the primary purpose of providing a location for shared disk access, i.e. shared storage of computer files (such as documents, sound files, photographs, movies, images, etc.) that can be accessed by the PCs that are connected to the computer network. But the disadvantage of it was that if the server fail may cause the operation of the school to a halt. Database server - A server that provides database services to other workstations or server. (SQL) Print server - A server that manages the different requests for printing. ICT499 CAPSTONE PROJECT REPORT 21 3.3 Facilities features Facilities of a typical primary school that needed to be networked: Figure 3.1 - Networked classroom Classrooms - A networked classroom illustrated in figure 3.1 would be equipped with a teaching desktop PC, a teaching laptop which is connectable to the school network & the short throw digital projector, and a visualiser. Networking enable the teaching staff to make use of the shared resources like file server or interactive soft/hardwares to enrich the class work and support the range of educational programmes provided Principals' office - A networked office would be equipped with a desktop PC to handle his daily works. And it enable the principal to make use of the shared computer resources like printer and also provided internet access. Vice-principals' office - Similar to the principal's office this networked office would be equipped with a desktop PC to handle the daily works. It enable the vice-principal to make use of the shared computer resources and also provided access to the internet. ICT499 CAPSTONE PROJECT REPORT 22 Figure 3.2 - Networked staff office Staff office - A networked staff office illustrated in figure 3.2, each staff should be equipped with a laptop connectable to the school network which enable the staff to utilize the shared computer resources and access to internet. Admin office - A networked admin office, each staff should be equipped with a laptop connectable to the school network which enable the staff to utilize the shared computer resources like printer & database server and access to internet. ICT servers & equipments room - A room equipped with the maintenance PC, routers, switches and servers to network the school facilities. Meeting room - - A networked meeting room should be equipped with a desktop PC, a short throw digital projector, and a visualiser for meeting purposes. Networking enable the staff to make use of the shared resources like file server to store meeting materials. General purpose room - A general purpose room are networked with a desktop PC to provide ICT capability when needed. ICT499 CAPSTONE PROJECT REPORT 23 IT resources room - The networked IT resources room provide student to make use of the shared resources available in the room and enable they to store their work in the file server. Teaching staff are able to make use of the capability of the room provided to enrich their teaching for the students. Science Laboratory - Similar to the networked classroom, teaching staff able to project teaching materials using the projector. Figure 3.3 - Networked computer lab Computer laboratory - The networked computer Lab illustrated in figure 3.3 provide student to make use of the shared resources available in the room and enable them to store their work in the file server. It is also able to provide internet access to the internet. Library - A networked library enable the students to make use of the multi-media PC to play different media, a library database PC to search the library for needed resources using the database store in the database server and admin PC for the use of librarians to handle borrowing and returning of books which save the records in the database server.. ICT499 CAPSTONE PROJECT REPORT 24 School hall - A networked school hall enable the hall to present materials or information through projector during school event. It also enable to play videos or music and internet materials when needed. School's Wi-Fi Corner - Provided internet access to teaching staff when needed. Enable the students to make use of wireless tablets during outdoor teaching. ICT499 CAPSTONE PROJECT REPORT 25 Chapter 4 - Design 4.1Network configuration There are two types of network configuration, peer-to-peer networks and client/server networks. Figure 4.1 - Peer to Peer network configuration Peer-to-peer networks illustrated in figure 4.1 are more commonly implemented where less than ten computers are involved and where strict security is not necessary. All computers have the same status, hence the term 'peer', and they communicate with each other on an equal footing. Files, such as word processing or spreadsheet documents, can be shared across the network and all the computers on the network can share devices, such as printers or scanners, which are connected to any one computer. The advantages of peer-to-peer networks are easy to set up, less expensive to install compare to client/server network, can implement on a variety of operating systems(OS) and it does not required a server to operate but the network would be time consuming when need to manage its software and applications as each software is located at different PC, it provide very low level security or no security at all and needed only moderate skills of a IT administrator to administer the network. ICT499 CAPSTONE PROJECT REPORT 26 Figure 4.2 - Client/server network configuration Client/server networks illustrated in figure 4.2 are more suitable for larger networks. A central computer, or 'server', acts as the storage location for files and applications shared on the network. Usually the server is a higher than average performance computer. The server also controls the network access of the other computers which are referred to as the 'client' computers. Typically, teachers and students in a school will use the client computers for their work and only the network administrator (usually a designated staff member) will have access rights to the server. This network are more difficult and expensive to setup compare to peer-topeer network. A variety of OS can be implemented on the client but the server would need to operate on a server OS. A centralized server would be less time consuming to maintain, update and administer. Provided high level of security and no limits to the number of users and computer hardware that can be supported. This network would required high level of skills and a good knowledge on server OS from the IT administrator. Based on the investigation on different network configuration, client/server network configuration are the suitable choice for this project. As this project network need to support large number of users and the high level of security to meet the needs of different group of user. Maintenance cost of the network is ICT499 CAPSTONE PROJECT REPORT 27 low due to the centralized configuration. IT administrator of this type of configuration is easily available as well due to the popular of this configuration. ICT499 CAPSTONE PROJECT REPORT 28 4.2 Network type Today's most common network types include Ethernet, token ring, and Asynchronous transfer mode (ATM) . Each of these three offers a viable alternative for supporting a LAN, each with its own costs and performance benefits ("soho3", 2011). Figure 4.3 - Token ring network type Token ring network type illustrated in figure 4.3 are all the computers are arranged schematically in a circle using token passing protocol to send message around the computer network. The only reason to even consider basing a small business network design on token ring is in deference to some prevailing concern, such as compatibility with a larger organizational network ("soho3", 2011). Asynchronous transfer mode (ATM) follows a fundamentally different approach. In an ATM network, data are broken into small fixed-size cells and switched in virtual circuits established between computers. Most ATM networks operate at a very respectable speed. Today, ATM is mostly found as the backbone technology for computer networks. ATM switches require a significant effort to configure. Usually an ATM network type is employ only ICT499 CAPSTONE PROJECT REPORT 29 if it required an extremely high-performance network to support data-intensive applications such as large-scale imaging projects ("soho3", 2011). Ethernet is the inexpensive and flexible choice to employ for a computer network. Today, most desktop PC come with Ethernet ports integrated onto the motherboard. Ethernet is associated with a set of networking rules called CSMA/CD (Carrier Sense Multiple Access with Collision Detection), formally specified by IEEE 802.3. These network rules describe how devices on the network communicate with one another. Ethernet is a broadcast network, in which all nodes have access to all data packets. Each packet has an origin and destination address, and each computer should open the packet only if the destination address matches its own network address. The network supports multiple devices per segment, and each device can transmit on the network at any time. If devices transmit exactly at the same time, however, a collision occurs and the transmissions are lost. Therefore, each station must check after it transmits to see if a collision occurred and, in the event of a collision, wait a random interval and retransmit. Most varieties of Ethernet operate at 100 Mbps, and each of the nodes on a segment share this bandwidth. The stations on a segment share the overall available bandwidth and can cause collisions with one another in the process. The amount of overall bandwidth available to each station decreases and the likelihood of excessive collisions goes up as the number of stations per segment increases. The lower the number of stations per segment, the better the network will function ("soho3", 2011). Example of Ethernet are Fast Ethernet at 100Mbps and Gigabit Ethernet at 1000Mbps. Bases on the study of the network types, Ethernet was the obvious option for this project. The cost efficiency advantage of this network type would reduce the cost of implementing the network which suit this project. IT administrator who are skilled or have good knowledge on Ethernet are easily available. The ICT499 CAPSTONE PROJECT REPORT 30 available of Fast Ethernet and Gigabit Ethernet would suit the different needs and requirements required by the school computer network. ICT499 CAPSTONE PROJECT REPORT 31 4.2 IP Addressing Scheme design For this project, a structured address assignment model would be employed to design the school computer network. Structured address assignment model enable easier troubleshooting while it also help the designer in interpreting the network maps and locate specific equipment on the network. This model maximize network scalability and stability. Standard practices of address assignment are assigning static addresses to routers and servers but use dynamic addresses for workstations in the network. This IP addressing scheme minimizes manual addressing, reducing the chances of address duplication and stabilizing the network’s addressing structure. Meaningful numbers can be assign when using static addresses; for example, reserve host addresses in the low or high portion of the range, and manually assign these addresses to routers or servers ("technet", 2011). Compare to static addresses by using dynamic addresses(DHCP) for clients in the project network are more time-saving and less prone to error because DHCP server automatically allocates IP addresses and would be useful on the project network which have frequent configuration changes. Another advantages of dynamic addresses are it easier to configure and requires minimal maintenance after the implementation. The table 4.1 below shown the estimation of host that would be utilizing the project computer network, Estimate Number of ICT499 CAPSTONE PROJECT REPORT Network Address Subnet Mask Max No. of Host Network Name 32 Maximum Host Available Address Required 230 192.168.0.0 255.255.255.0 254 Class Vlan 200 192.168.1.0 255.255.255.0 254 Lab Vlan 200 192.168.2.0 255.255.255.0 254 Wireless Vlan 50 192.168.3.0 255.255.255.128 127 Staff Vlan 3 192.168.3.128 255.255.255.224 31 Server Vlan 24 192.168.3.160 255.255.255.224 31 IT Administrator Vlan 2 10.0.0.0 255.255.255.0 -- Link router0 and ISP 2 172.0.0.0 255.255.255.0 -- Link router1 and ISP 2 200.200.1.0 255.255.255.0 -- Link ISP and HTTP Table 4.1 - Host estimation table For this project, four subnets would be utilize to support the six Vlan identified. An estimated total of at least 707 host addresses would be needed for the project network. Subnets 1. 192.168.0.0 2. 192.168.1.0 ICT499 CAPSTONE PROJECT REPORT 33 3. 192.168.2.0 4. 192.168.3.0 Vlan 1. Class Vlan 2. Lab Vlan 3. Wireless Vlan 4. Staff Vlan 5. Server Vlan 6. IT administrator Vlan ICT499 CAPSTONE PROJECT REPORT 34 4.3 Network diagram design Network model Figure 4.4 - Project Network Model ICT499 CAPSTONE PROJECT REPORT 35 Network diagram Figure 4.5 - Network Diagram ICT499 CAPSTONE PROJECT REPORT 36 Chapter 5 - Project Management 5.1 Methodology This project requires planning and analysis, feasibility studies, capacity planning, and baseline creation in order to develop the computer network design. SDLC or Systems Development Life Cycle will be apply as the methodology, or plan for a structured approach to the development of the project. Systems Development Life Cycle involves these cyclical phases: Planning - Identify the problems, opportunities, and objectives. Analysis - Determine requirements. Design - Design the system. Implementation - Install the system and migrate from old to new. Evaluation - Evaluate the performance and verify that all requirements & objectives are meets. Planning Phase Identify the objectives of developing the computer network design. Identify main networking components. Identify the problems that will be face in developing this project Identify the value of this project. Prepare Project Proposal. (Unisim) Analysis Phase ICT499 CAPSTONE PROJECT REPORT 37 Determine the requirements of a typical primary school by gathering information using sampling and collecting hard data, interviewing, questionnaires, observing the school environments, and prototyping. Determine how the new network will operate. Determine the topological design. Determine the technical details of the network's capabilities. Determine the protocols technologies for the computer network. Determine the computer simulation software to be use. Determine the equipments required to implement the network. Perform feasibility studies. Prepare Interim Report. (Unisim) Design Phase Design the topological design. Design the IP addressing scheme Design the network model Design the physical layout of network diagram. Implementation Phase Simulate the implementation of the network using computer simulation software. Evaluation Phase Verify all network requirements are meets. Evaluate the performance of the computer network. Create baseline. Prepare Project Poster. (Unisim) ICT499 CAPSTONE PROJECT REPORT 38 Prepare Project Report. (Unisim) Prepare Project Presentation. (Unisim) ICT499 CAPSTONE PROJECT REPORT 39 5.2 Schedule Project Activity list This project activity list illustrated in table 5.1 is an documentation of all of the scheduled activities that are part of this project. Information consists of the unique activity identifier, activity description, duration given to complete and start/end date of the activity are included in the list. S/n Task Name Start of Project 1 Planning Phase 1.1 Capstone Commencement Briefing 1.2 Identify Project Objectives 1.3 Identify Project's Problems 1.4 Tutorial 1 - Proposal discussion 1.5 Tutorial 2 - Proposal discussion 1.6 Prepare Project's Proposal 2 Analysis Phase 2.1 Determine Network Requirements 2.2 Determine Network Topology design 2.3 Determine Network's Capabilities 2.4 Determine Protocols & Technologies 2.5 Tutorial 3 - Proposal Feedback 2.6 Determine Computer simulation software 2.7 Determine network equipments 2.8 Perform feasibility studies 2.9 Tutorial 4 - Progress meeting 2.10 Tutorial 5 - Progress meeting 2.11 Prepare Interim Report 3 Design Phase 3.1 Design network topology 3.2 Design IP addressing Scheme 3.3 Design network diagram 3.4 Design physical layout of network diagram 3.5 Implementation Phase 3.6 Tutorial 6 - Progress meeting 3.7 Simulate the computer network using Cisco Packet Tracer 4 Evaluation Phase ICT499 CAPSTONE PROJECT REPORT Duration 218 days 22 days 1 day 2 days 2 days 1 day 1 day 16 days 45 days 4 days 3 days 3 days 3 days 1 day 2 days 2 days 2 days 1 day 1 day 24 days 19 days 4 days 5 days 5 days 5 days 30 days 1 day 30 days 35 days Start 07/08/2010 07/08/2010 07/08/2010 09/08/2010 11/08/2010 13/08/2010 27/08/2010 16/08/2010 07/09/2010 07/09/2010 13/09/2010 16/09/2010 21/09/2010 24/09/2010 27/09/2010 29/09/2010 01/10/2010 05/10/2010 22/10/2010 06/10/2010 06/10/2010 06/10/2010 12/10/2010 19/10/2010 26/10/2010 15/11/2010 26/11/2010 15/11/2010 27/12/2010 End 04/06/2011 06/09/2010 07/08/2010 10/08/2010 12/08/2010 13/08/2010 27/08/2010 06/09/2010 08/11/2010 10/09/2010 15/09/2010 20/09/2010 23/09/2010 24/09/2010 28/09/2010 30/09/2010 04/10/2010 05/10/2010 22/10/2010 08/11/2010 01/11/2010 11/10/2010 18/10/2010 25/10/2010 01/11/2010 24/12/2010 26/11/2010 24/12/2010 11/02/2011 40 4.1 4.2 4.3 4.4 4.5 4.6 4.7 5 5.1 5.2 5.3 5.4 5.5 5.6 Tutorial 7 - Progress meeting Verification of requirements Testing of simulation Tutorial 8 - Project Report Meeting Evaluate design performance Project Report Preparation Project Report and Poster Design Briefing Project Report writing Phase Tutorial 9 - Project report meeting Tutorial 10 - Project report meeting Project report finalizing Project report binding Submit Project report Project Presentation Table 5.1 - Project Activity List table 1 day 10 days 16 days 1 day 8 days 82 days 1 day 36 days 1 day 1 day 10 days 15 days 1 day 1 day 27/12/2010 28/12/2010 11/01/2011 04/02/2011 02/02/2011 14/02/2011 19/02/2011 14/02/2011 11/03/2011 08/04/2011 04/04/2011 18/04/2011 16/05/2011 04/06/2011 27/12/2010 10/01/2011 01/02/2011 04/02/2011 11/02/2011 04/06/2011 19/02/2011 01/04/2011 11/03/2011 08/04/2011 15/04/2011 06/05/2011 16/05/2011 04/06/2011 The total effort required for this project is 218 man-days or 1417 hours. If there are any delay in the completion of each task, buffer would be allocate from activity "Project Report Preparation". ICT499 CAPSTONE PROJECT REPORT 41 Project Gnatt Chart 07/08/10 to 26/09/10 Figure 5.1 - Gnatt Chart diagram ICT499 CAPSTONE PROJECT REPORT 42 27/09/10 to 18/11/10 Figure 5.2 - Gnatt Chart diagram ICT499 CAPSTONE PROJECT REPORT 43 19/11/10 to 09/01/11 Figure 5.3 - Gnatt Chart diagram 3 ICT499 CAPSTONE PROJECT REPORT 44 10/01/11 to 03/03/11 Figure 5.4 - Gnatt Chart diagram 4 ICT499 CAPSTONE PROJECT REPORT 45 04/03/11 to 25/04/11 Figure 5.5 - Gnatt Chart diagram 5 ICT499 CAPSTONE PROJECT REPORT 46 26/04/11 to 04/06/11 Figure 5.6 - Gnatt Chart diagram 6 ICT499 CAPSTONE PROJECT REPORT 47 5.3 Risk assessment Project and Task number Risk Event Probability Impact (H/M/L) Overall Risk 059/1.1 Unable to attend Capstone Project Briefing M M M 059/1.4 Unable to attend the arranged tutorial H M H 059/1.6 Fail to submit Project Proposal L H H 059/2.1 Unable to determine requirements for the project L H H 059/2.8 Project not feasibility L H H 059/2.9 Fail to submit Interim Report L H H 059/3.7 Unable to simulate the network using Cisco Packet Tracer L H H 059/4.1 Project progress latency H H H 059/5.0 Fail to submit Project Poster L H H 059/5.5 Fail to submit Project Report L H H 059/5.6 Fail to turn up for Project Presentation L H H 059/4.2 Requirements not meet M H H 059/4.3 Simulation fail M H H ICT499 CAPSTONE PROJECT REPORT Risk Response Approach Supervisor for detail needed Arrange another date with supervisor Approach Supervisor for advice Revise the project Revise the project Approach Supervisor for advice Approach Supervisor for help Reschedule the progress Approach Supervisor for advice Approach Supervisor for advice Approach Supervisor for advice Approach Supervisor for advice Approach Supervisor for advice 48 059/4.5 Performance not up to standard Table 5.2 - Risk Assessment table ICT499 CAPSTONE PROJECT REPORT M H H Approach Supervisor for advice 49 Chapter 6 - Investigation and Experiment 6.1 Comparison of physical network topologies Network topology is defined as the interconnection of the various elements (links, nodes, etc.) of a computer network. Topologies can be physical or logical. ("Network topology", 2010) Physical topologies - The physical design of a network including the devices, location and cable installation. ICT499 CAPSTONE PROJECT REPORT 50 Figure 6.1 - Physical topologies diagram Star - All devices are connected to a central hub. Nodes communicate across the network by passing data through the hub. Mesh - Devices are connected with many redundant interconnections between network nodes. In a true mesh topology every node has a connection to every other node in the network. Bus - All devices are connected to a central cable, called the bus or backbone. Ring - All devices are connected to one another in the shape of a closed loop, so that each device is connected directly to two other devices, one on either side of it. Tree - A hybrid topology. Groups of star-configured networks are connected to a linear bus backbone. ("topologies", 2011) Below table 6.1 was the summary of the advantages and disadvantages of each physical network topology. Topologies Advantages Bus Ring Star Easy installation Easy installation Easy installation Low cost Low cost Simple addition of new system ICT499 CAPSTONE PROJECT REPORT Tree/Hybrid Simple addition of new Depend on system topologies Simple addition of new One break does not bring used in the Hybrid. system whole network down Mesh Extremely fault tolerant 51 Easier to troubleshoot Disadvantages Small networks (Suitable) Small networks (Suitable) Outdated technology Outdated technology Network down if cable Network down if cable breaks breaks Difficult to troubleshoot Difficult to troubleshoot Large networks (Not Large networks (Not suitable) suitable) Widely used Centralized management Expensive High cost Difficult to Depend on topologies Network down when central device fails used in the Hybrid. implement Difficult to administer Difficult to troubleshoot Table 6.1 - Physical Topologies table From the investigation of the physical network topologies, star network topology would be employed as the physical network topology in this project. ICT499 CAPSTONE PROJECT REPORT 52 6.2 Comparison of logical network topologies Logical topology - How data is actually transferred in a network. Below table 6.2 was the summary of the advantages and disadvantages of each logical network topology. Detail of the each logical network topology is described in "4.2 Network type" under chapter 4. Topologies Ethernet (Shared Media) Unrestricted access to the physical media Token Based No collisions ATM High network performance Advantages Inexpensive Suitable for small network Latency Disadvantages Collisions Suitable as a backbone technology Difficult to configure Restricted access to the physical media Expensive (Needed Token) Table 6.2 - Logical Topologies table In this project shared media topology (Ethernet) will be employ as the logical topology. ICT499 CAPSTONE PROJECT REPORT 53 6.3 Hardware Hardware required: Figure 6.2 shown the Fast Ethernet or 100BASE-TX - Cat5e 100 Mbps, ideal for sending large, complex files such as databases and graphics. Figure 6.2 - Cat5e Ethernet cable Figure 6.3 shown the Gigabit Ethernet - Cat6 1000 Mbps, excellent solution for those using bandwidth-intensive applications and where high volume traffic exists. Figure 6.3 - Cat 6 Ethernet cable ICT499 CAPSTONE PROJECT REPORT 54 Figure 6.4 shown the Firewall - it serves as a security guard, protecting the school network from unauthorized entry. Figure 6.4 - Cisco PIX 506E Figure 6.5 shown the Switch - direct traffic only to their destinations, such as a printer, server, router or another user. ICT499 CAPSTONE PROJECT REPORT 55 Figure 6.5 - Cisco 2960 Switch Figure 6.6 shown the Router - interconnects two or more computer networks, and selectively interchanges packets of data between them. Figure 6.6 - Cisco 2811 router Figure 6.7 shown the Classroom PCs or admin PCs - PCs available for teaching purposes in the classroom and administration purposes. ICT499 CAPSTONE PROJECT REPORT 56 Figure 6.7 - Desktop PC Figure 6.8 shown the Staff Computers (Laptop) - Connectable to the network and fixed digital projector in order to access and show digital content Figure 6.8 - Laptop Figure 6.9 shown the School servers - Provide server functions for the network which was load with a server OS. ICT499 CAPSTONE PROJECT REPORT 57 Figure 6.9 - Server Figure 6.10 shown the Wireless tablet - allows teachers and students to draw, illustrate or write and project this through the digital projector onto any projection surface. Figure 6.10 - Wireless tablet Figure 6.11 shown the Wireless access point - Connect computers together without the use of cables, use wireless radio signals to send information. ICT499 CAPSTONE PROJECT REPORT 58 Figure 6.11 - Wireless Access point All hardwares required in setting up the primary school computer network will be supplemented by using the computer simulation software in this project. ICT499 CAPSTONE PROJECT REPORT 59 Below are some of the ICT based teaching products that can be implemented, Figure 6.12 shown the Short throw projector - Uses to project teaching materials for students. Figure 6.12 - Short Throw Projector Figure 6.13 shown the Visualisers - Visualise teaching material without the needs to print out on paper. Figure 6.13 - Visualisers Figure 6.14 shown the Interactive Whiteboard - Able to integrate a wide range of teaching material into a lesson. Promote interactivity between teachers and students. ICT499 CAPSTONE PROJECT REPORT 60 Figure 6.14 - Interactive Whiteboard Figure 6.15 shown the Learner Response Systems - Able to engage, motivate and empower each student. Work with personalised learning software to allows students to work at their own level and pace. Figure 6.15 - Learner Response System Another advantages of implementing ICT in the classroom are assistive technology. Assistive technology is any item, piece of equipment or product system that is used to improve functional capabilities of students with disabilities ("Assistive Technology", 2011). ICT499 CAPSTONE PROJECT REPORT 61 Alternative Keyboards Alternative Mice Switches Touch Screens Augmentative and Alternative Communications Portable Devices ICT499 CAPSTONE PROJECT REPORT 62 6.4 Software Cisco Packet Tracer supplements physical equipment by allowing user to create a computer network with an almost unlimited number of devices. It is a powerful network simulation program that allows user to experiment with network behaviour and ask “what if” questions. Packet Tracer able to provide simulation, visualization, authoring, assessment, and collaboration capabilities. The logical workspace illustrated in Figure 6.16 allows users to build logical network topologies by placing, connecting, and clustering virtual network devices. Figure 6.16 - Logical Packet Tracer Simulation example 1 The physical workspace illustrated in Figure 6.17 provides a graphical physical dimension of the logical network, giving a sense of scale and placement in how network devices such as routers, switches, and hosts would look in a real environment. ICT499 CAPSTONE PROJECT REPORT 63 Figure 6.17 - Physical Packet Tracer Simulation example 2 Cisco Packet Tracer provides two operating modes to visualize the behaviour of a network—real-time mode and simulation mode. In real-time mode the network behaves as real devices do, with immediate real-time response for all network activities. The real-time mode gives user a viable alternative to real equipment and allows them to gain configuration practice before working with real equipment. In simulation mode the user can see and control time intervals, the inner workings of data transfer, and the propagation of data across a network. This helps user understand the fundamental concepts behind network operations. (”Cisco Packet Tracer DS", 2010) In this project, Cisco Packet Tracer will be uses to develop the logical computer network design and the simulation of the network of the primary school. ICT499 CAPSTONE PROJECT REPORT 64 Other example of simulation software: Figure 6.18 - NetSim Simulation example 1 Similar to Packer Tracer, Boson NetSim Network Simulator illustrated in Figure 6.18 is an application that simulates Cisco Systems' networking hardware and software but the main difference was that NetSim was able to build an appropriate virtual routing table and simulate true networking traffic. Its capability to simulates network traffic with virtual packet technology would be a real value asset required to evaluate the network traffic's performance of the computer network in a simulation environment before implementation. A expensive option but would able to provide the required ability for any network engineer to design their computer network in a simulation environment. Required a good knowledge of operating the software. ICT499 CAPSTONE PROJECT REPORT 65 Figure 6.19 - GNS3 Simulation example 1 An inexpensive option for simulation of a computer network because it was an open source and free program available for download. Similar to Packet Tracer, GNS3 is a graphical network simulator illustrated in Figure 6.19 that allows simulation of complex networks that simulates on Cisco equipments. Unlike NetSim this software was not able to simulate real network traffic for testing purposes. Disadvantages of this software are it was not very userfriendly compare to the two simulation software mentioned above. And there are a need to download other programs to allow full simulation. ICT499 CAPSTONE PROJECT REPORT 66 6.5 Evaluation In this chapter, different physical/logical network topologies are investigated. Based on the their advantages/disadvantages and suitability for the project, Star physical network topology and Shared Media or Ethernet are selected for this project's computer network. The advantages of easy installation and simple addition of new network equipments or computer hardwares ensure that the future expansion of the school computer network would have with no trouble in its implementation. The probability of total failure of the computer network was minimized because one break of the network would not causes the whole network to be down. Due to the popularity of this type of physical and logical topology, cost of setting up was reduced. Compare to other topologies, the centralized structure ensure that it was easier to troubleshoot any problems. A potential problem exist in the type of physical network topology chosen was if a centralized equipment was down, may caused the failure of the network. But this problems can be solved by ensuring a failover device was ready to take over when the failure of the active device occur. From the figure 4.5 in chapter 4 shown the design of a network diagram with a active router and a passive or failover router ready to take over when failure occur. The network diagram also shown that by dividing each parts of the school to different switches would minimize the risk of total failure of the computer network. Collision would be a potential problem in the network too but by ensuring different segments of the network is separated to different switches would help relieve this problem. Different type of network and computer hardwares that are needed to set up the computer network are identified in the investigation for this project. Different types of ICT-based teaching equipments are introduced in this chapter so as to illustrate that the implementing of ICT technology in ICT499 CAPSTONE PROJECT REPORT 67 classroom would broaden the range of educational programmes enable to be put into service for the students. Lastly was the selection of the simulation software for this project. Packet Tracer 5.3 was selected for its user-friendly interface and capability to simulates Cisco Systems' networking hardware/software but there would be a lack of a critical function which is the simulation of network traffic. Investigation shown that NetSim proved to be a better choice in the simulation of the project than Packet Tracer but NetSim required a higher technical knowledge in order to utilize it and the cost of obtaining the software is high. ICT499 CAPSTONE PROJECT REPORT 68 Chapter 7 - Simulation 7.1 Network simulation model Figure 7.1 below illustrated the logical network simulation model created by Packet Tracer 5.3 simulation software for this project computer network. ICT499 CAPSTONE PROJECT REPORT 69 Figure 7.1 - Project Simulation model ICT499 CAPSTONE PROJECT REPORT 70 Simulation of the school computer network are based on the floor map design illustrate in floor map section of Appendix B. Figure 7.1.2 - Vlan and Sub interface addresses Figure 7.2 - Simulation main routers/switches The computer network designed illustrated in figure 7.2 was support by one active router (Router1) and one passive/failover router (Router0) which connect to the router simulating ISP service. Main Switch0 was connected to switches of Level 2 & 3facilities and main Switch1 connected to switches of level 1 & 4, servers and wireless corner facilities. This design follow the Star physical topology selected. A IT administrator PC was connected to main Switch1 to perform maintenance services for the network. ICT499 CAPSTONE PROJECT REPORT 71 Figure 7.3 - Simulation of Level 1 This section illustrated in figure 7.3 shown the switches connecting to main Switch1 and the level 1 facilities connecting to the network. Figure 7.4 - Simulation of Wireless Corner This part of the simulation illustrated in figure 7.3 display the wireless corner of the school network. A wireless switch connected to the main Switch1 and two different wireless access points providing different functions. One was for providing internet access in the area and another one was for conducting outdoor teaching. ICT499 CAPSTONE PROJECT REPORT 72 Figure 7.5 - Simulation of Level 2 This section illustrated in figure 7.5 shown the switches connecting to main Switch0 and the level 2 facilities connecting to the network. Figure 7.6 - Simulation of Level 2 Servers This section illustrated in figure 7.6 shown the switches connecting to main Switch1 and the different types of server connecting to the network. ICT499 CAPSTONE PROJECT REPORT 73 Figure 7.7 - Simulation of Level 3 This section illustrated in figure 7.7 shown the switches connecting to main Switch0 and the level 3 facilities connecting to the network. ICT499 CAPSTONE PROJECT REPORT 74 Figure 7.7 - Simulation of Level 4 This section illustrated in figure 7.7 shown the switches connecting to main Switch1 and the level 4 facilities connecting to the network. ICT499 CAPSTONE PROJECT REPORT 75 7.2 Network simulation features The first feature of this simulation model are the controlled access to the simulation HTTP server by passing the ISP router. Iillustrated in figure 7.8 & 7.9 was the screenshot of the successful and unsuccessful attempt. Only Vlan 3, 4, 5 &7 are allowed to access the simulated internet in this simulation network. Figure 7.8 - Simulation of successful internet attempt ICT499 CAPSTONE PROJECT REPORT 76 Figure 7.9 - Simulation of unsuccessful internet attempt The second feature illustrated in figure 7.10 of this simulation model are the capability of only IT administrator was able to telnet to all routers and switches in the network to perform maintenance services. ICT499 CAPSTONE PROJECT REPORT 77 Figure 7.10 - Simulation of telnet access The third feature illustrated in figure 7.11 of this simulation model are the FTP server created to act as the storage server in the network. All users of the network would be able to connect to the FTP server and use it depend on the account assigned to them. Figure 7.11 - Simulation of FTP access Figure 7.12 - Simulation of ICMP testing between facilities This feature illustrated in figure 7.12 was employ to test the ICMP connection which was similar to the "Ping" function between the facilities connected to the network. ICT499 CAPSTONE PROJECT REPORT 78 Figure 7.13 - Simulation mode of Packet Tracer In simulation mode this feature illustrated in figure 7.13 enable the user to see and control time intervals, the inner workings of data transfer, and the propagation of data across the network defined by the scenario created. Due to the limitation of Packet Tracer 5.3 software, network features like auto switchover from active to passive router and the restriction access of users connecting to the network based on time and date were not able to implement in the simulated network. ICT499 CAPSTONE PROJECT REPORT 79 7.3 Network configuration Network configuration code of routers and switches for this project simulation computer network are illustrated under Simulation model configuration of Appendix B in this report. Username/Passwords for routers & switches and WEP key of all the wireless access point are also included in the Simulation Model Passwords & WEP Key of Appendix B. 7.4 Virtual Local Area Network Network Max No. of Internet address host Access 2 192.168.0.0 254 No Lab Vlan 3 192.168.1.0 254 Yes Wireless Vlan 4 192.168.2.0 254 Yes Staff Vlan 5 192.168.3.0 127 Yes Server Vlan 6 192.168.3.128 31 No IT admin Vlan 7 192.168.3.160 31 Yes Vlan Name Vlan Number Class Vlan Table 7.1 - Vlan table All simulated Vlan shall be able to connect to each other in the network. Only access to the simulated HTTP server was controlled. Further expansion of network can be done by adding new Vlan. 7.5 IP addressing scheme IP addressing scheme, router interface scheme and switch interface scheme employed for this project simulation computer network are illustrated under Appendix A in this report. ICT499 CAPSTONE PROJECT REPORT 80 IP addressing scheme of the project would include information of number of host address required, network address, subnet mask, total number of used IP address & available IP address, maximum number of host available and the network name. Router interface scheme consists of information like description and purpose of each interface on the router and the network information each interface connect from/to. Switch interface scheme consists of information like description and purpose of each interface on the switch, the network information each interface connect from/to and the switch port type of each interface. 7.6 Testing Test results for this project simulation computer network are illustrated in Appendix C. Simulation test results include of: ICMP connection between Vlan DHCP connectivity Vlan connectivity to the HTTP server. Telnet results to all routers and switches from the IT admin PC FTP connectivity of users Scenario illustrated in table 7.2, 7.3 & 7.4 would be used for testing in Packet Tracer simulation mode Scenario 0 - Class Vlan to different Vlan From To Type 2A PC 2B PC ICMP ICT499 CAPSTONE PROJECT REPORT 81 2A PC Lab 3 PC ICMP 2A PC 4M wireless tablet ICMP 2A PC General Purpose ICMP PC 2A PC File server ICMP 2A PC IT admin PC ICMP Table 7.2 - Scenario 0 table Scenario 1 - Server Vlan to different Vlan From To Type DHCP Server 1A ICMP DHCP Server Lab 3 PC ICMP DHCP Server Wireless PC ICMP DHCP Server Vice-principal PC ICMP DHCP Server FTP server ICMP DHCP Server IT admin PC ICMP Table 7.3 - Scenario 1 table Scenario 2 - IT admin Vlan to different Vlan From To Type IT admin PC 3F PC ICMP IT admin PC Hall PC ICMP IT admin PC Science Lab 1 PC ICMP IT admin PC 4N Wireless ICMP tablet IT admin PC DHCP Server ICMP IT admin PC IT admin PC ICMP Table 7.4 - Scenario 2 table ICT499 CAPSTONE PROJECT REPORT 82 7.7Evaluation In this chapter, the simulation of the computer network is illustrated and defined. The simulated computer network are segmented bases on the floor level, location of the facilities and the types of facilities in the computer network. In this way the presentation of the simulation network allowed the network to be easy to understand by the stakeholders and equipments in the network can be located more effortlessly. The network structure of the simulation was based on the investigation in this report, using the selected Server/Client network configuration, Star network topology and Ethernet logical network topology which was believed to be the most suitable for this project. By using the Packet Tracer simulation software, the network could be implemented with features include of DHCP addressing for client users, creation of a simulated HTTP server for internet access, telnet access for maintenance purposes and the setup of a FTP server to simulate as a storage server. Packet Tracer also provided built in testing mechanism to test the ICMP connection between the facilities connected to the network. Simulation mode of Packet Tracer allow designer to observe the inner workings of data transfer, and the propagation of data across the network so as to identify problems earlier before the implementation start. Through the investigation, better simulation software like NetSim was found which was able to provide additional functions for the simulation network like the utilize of latest version of routers/switches and the capability to simulate real network traffic which Packet Tracer cannot. The simulated compute network's IP addressing scheme was constructed based on the structured assignment model discussed in the previous chapter. The IP addressing scheme developed are believed to be able to support the number of users needed, while segmented the different group of users into ICT499 CAPSTONE PROJECT REPORT 83 different Vlan and record down detail information on each router and switch needed in the network. Testing results shown that all facilities in the simulated network are connected. All clients are able to use DHCP for dynamical addressing for the computer hardware. Only the intended Vlan are able to access internet. Maintenance services can be provide from a centralized location to all network equipments. Only users with the admin right access can delete and write the FTP server. Result obtained for the different scenario in the simulation mode are accurate. ICT499 CAPSTONE PROJECT REPORT 84 Chapter 8 - Conclusion and recommendation The computer network this project designed must be able to meet the identified design considerations, requirements and the needed features of a typical primary school's computer network in order to be considered as an optimized computer network intended to be develop for this project. The assessment of a complete set of requirement, feature and design consideration allowed the network designed to have a set of guideline to follow during the whole project development phase. The feasibility studies on the design considerations, requirements and features clearly shown that an optimized computer network can be created if the computer network were able to meet the requirements identified, having the features needed in the network and utilize the selected network configuration & physical/logical network topology. In this project, the structured address assignment approach shown clearly that it was very suitable to be employ for the project's computer network. Another finding was that setting up of the physical computer network in real life can be based on the location of the facilities in the school, floor level of the school and the types of facilities so as to save on cost of cabling and exploit the cost-saving feature of a centralized design.The structured approach of System Development Life Cycle (SDLC) employed on the development of this project allowed the project to be well-organized and efficiently completed. The second main part of this project was to evaluate the computer network design process employed in this project to the traditional network design process. The development of a simulation model of the computer network designed in this project clearly shown that the benefits and advantages identified for using of simulation in the report. ICT499 CAPSTONE PROJECT REPORT 85 In this project a simulation of the network designed for this project was created in order to demonstrate that this approach employ in the project is possible and advisable to employ. But if the simulation of this project was able to generate real network traffic the design of the project network would be even more improved. To conclude the report, the network design process employed in this project was found to be better than traditional design process and majority of the design consideration, requirement and feature are identified. Recommendation: The computer network can be further modified/enhanced its functionalities and to be build more closely to the user requirements, 1. A better simulation software like NetSim 8.0 that can generate real network traffic can be utilize for the developing of the project's simulation computer network. 2. A more detailed analysis of requirements can to be conducted. 3. Can exploit better or newer routers or switches in the network ICT499 CAPSTONE PROJECT REPORT 86 Chapter 9 - Reflection This project present a lot of problems for me especially during the planning phase of the project, a lot of concerns like how to acquire the skills needed to complete the project, how to cope between this project and my other studies in Unisim, how I going to refresh the related knowledge I learned during my Polytechnic days and a lot more... But with the discussion with my project supervisor and the advices he given to me during the whole project period ensure that this project was successfully developed. He provided me with detailed information on what he expected from the project from the very beginning meeting. Always help me make the correct decision during each critical part of the project. Refreshing myself with network knowledge would be the first priority before starting my project. And next would be finalizing the objectives of the project and how the project would be developed. For skill review, I felt that the key skills really needed for the project are project management skill and Cisco router/switch configuration skill. This capstone project was a one year project that need careful planning and scheduling before it can begin but lucky for me the project management knowledge I learned during the studies in Unisim helped me a lot. I last configure a router was when I still studying in the Polytechnic, this project allow me to retain the skill of what I learn before. During this whole year of developing the project, I was able to practice and improve on both of this skills needed in the project. A lot of problems happen during the whole project period which caused the delay in progress of the project but it a good learning experience for me to deal & solve the problems with my project supervisor and friends. One of the significant problem was during the design phase of the project, I need to produce a optimized design of the network but the lack of real life network implementation experience resulting the design of my network to be not realistic to be implemented. After a good discussion with my supervisor and a ICT499 CAPSTONE PROJECT REPORT 87 network engineer friend, and spent a lot of time online searching for relevant information, and editing the design of network several time before the problem was solved. The next significant problem I faced was the insufficient time needed to develop the simulation model during the implementation phase. In the planning phase, I allocated 30 days to complete the simulation model but due to the examination period I needed that time to focus on my exam so the project was push back one month time and may caused the whole project to delay by one month. in order to solved this problem, a month buffer allocated from the writing report period so as to not affect the completion of the project. Anyway, I really learned a lot from the capstone project. The project present me with a lot of challenges and problems which needed me to resolve. And I have a better understanding of the project management techniques and skills that I learned which would be help me in my future work. The remind of my knowledge I learned during my polytechnic day and putting it to good use in the project. Lastly, now I'm confident to know that I can manage a IT network project efficiently. Total words - 10,430 ICT499 CAPSTONE PROJECT REPORT 88 References Computer Networking. Retrieved Mar 09, 2011 from http://en.wikipedia.org/wiki/Computer_network prime. Retrieved Mar 09, 2011 from http://www.moe.gov.sg/initiatives/prime/ Network planning and design. Retrieved , Mar 09 2011 from http://en.wikipedia.org/wiki/Network_planning_and_design#References International Institute for Learning, Inc (2011), Business Analysis Certificate Program (Book 1). International Institute for Learning, Inc DHCP. Retrieved , Mar 10 2011 from http://en.wikipedia.org/wiki/Dynamic_Host_Configuration_Protocol soho3. Retrieved , Mar 10 2011 from http://www.networkcomputing.com/netdesign/soho3.html technet. Retrieved , Mar 20 2011 from http://technet.microsoft.com/en-us/library/cc779481%28WS.10%29.aspx Network topology. Retrieved Apr 04, 2011 from http://en.wikipedia.org/wiki/Network_topology Assistive Technology. Retrieved Apr 04, 2011 from http://www.ncte.ie/SpecialNeedsICT/ResourcesAdvice/AssistiveTechnology/ topologies. Retrieved Apr 04, 2011 from http://www.webopedia.com/quick_ref/topologies.asp ICT499 CAPSTONE PROJECT REPORT 89 Appendix A Stakeholder Interest Impact High High PRIME project committee High High Principal High Low Teacher High Low Student High Low Parent Medium Low Low Medium Medium Low Ministry of Education (MOE) IT administrator Admin Staff Table 2.1 - Stakeholder Register Req ID S01 S02 S03 S04 S05 S06 Requirement Description The MOE shall be able to employ this project to improve the current primary school education system. The MOE shall be able to offer better school facilities for students. The MOE shall be able to provide a wide range of educational programmes. The MOE shall be able to upgrade or enhance current computer network or computer network design of primary school. The MOE shall be able to enhance or improve the data or voice communication between MOE and the schools. The project committee shall be able to employ this project for all the primary schools under the PRIME programme. Stakeholder MOE MOE MOE MOE MOE PRIME The project committee shall be able to employ this project as part S07 of the infrastructure design for the new or upgraded facilities PRIME developed under the PRIME programme. S08 The project committee shall be able to offer a physical ICT499 CAPSTONE PROJECT REPORT PRIME 90 environment with a optimized computer network that are beneficial to learning and creative thinking. The project committee shall be able to employ this project S09 approach of designing the computer network under the PRIME PRIME programme. The principal shall be able to utilize the variety of function and S10 facilities a computer network can offer to improve the education Principal model in the school. S11 S12 S13 S14 S15 S16 S17 S18 S19 S20 S21 The principal shall be able to improve the productivity of the school due to the IT networking of the whole school. The principal shall be able to exploit the benefits of the new or upgraded facilities. The principal shall be able to utilize lesser resources to complete the school objectives. The teacher shall be able to utilize more innovative& creative method of teaching in the class through the use of IT technology. The teacher shall be able to utilize the features that the computer network has to offer to do their job more efficiently. The student shall be able to benefit from the wide range of educational programmes. The student shall be able to be more IT savvy. The student shall be able to benefits from the more creative and innovative teaching. The parent shall be able to be provided with a more effective and faster administration service at the school. The IT administrator shall be able to perform the maintenance for the computer network using a centralized PC. The admin staff shall be able to perform their job more effectively and efficiently. Table 2.2 - Stakeholder Requirements Documentation ICT499 CAPSTONE PROJECT REPORT Principal Principal Principal Teacher Teacher Student Student Student Parent IT admin Admin Staff 91 Req ID Requirement Description F01 The network would enable interconnectivity of users and resources. F02 The network would support shared access for files and data. F03 The network would support resources sharing. F04 The network would support data transfer. F05 The network would allow bulk transfer. F06 The network would support FTP service. F07 The network would support multi-user database service. F08 The network would connect to the internet. F09 The network would support DHCP service. F10 The network would connect to a file storage server. F11 The network would have a centralized maintenance PC. F12 The network would support wireless technology and its equipments. The network would support a variety of computer hardware F13 including tablet-PC, laptop, desktop PC, printer, scanner and projector. F14 The network would maintain log for tracking & auditing. F15 The network would be able to support 3 to 4 servers. F16 The network would provide internet for specific group of users. F17 F18 F19 The network would control the internet speed for each group of users. The network would have a failover router, ready to takeover when the main router fail. The network would be subdivide into different Vlan based on different group of user. F20 Each Vlan will be allocate with enough IP address to support. F21 There would be enough IP addresses to be allocate for all users. F22 Each Vlan have different access rights to different Vlan. F23 Each computer Lab would support up to 40 PCs. F24 Each multi-media Lab would support up to 20 PCs. F25 Only the IT administrator PC can allocate administration rights. ICT499 CAPSTONE PROJECT REPORT 92 F26 F27 Different group of users would have different access rights to the servers. Different group of users would have different time limit access to the computer network. Table 2.3 - Functional Requirements Documentation Req ID nF01 nF02 nF03 nF04 nF05 nF06 nF07 nF08 nF09 nF10 nF11 nF12 nF13 Requirement Description The computer network would keep the servers & workstations in the school computer network anonymous. The computer network would includes a access policy to network services or content. Block undesired sites The computer network would offer security/ parental controls. The computer network would offer system security to limit access to files to specific users or groups. The computer network would scan outbound content for data leak protection. The computer network would scan transmitted content for malware or virus. The computer network would track and report successful and unsuccessful login access. The computer network would ensure confidential information is protected and encrypted. The system will be accessible and available to all authorized users 99.5 % of the time. The computer network's server response time for worst-case latency will be less than 100 millisecond. The computer network's DHCP service response time for worst-case latency will be less than 60 second. The computer network must not have more than one time of unplanned outrages. The computer network meantime between failures are one day. ICT499 CAPSTONE PROJECT REPORT 93 nF14 nF15 nF16 nF17 The computer network data transfer speed must be more than 10 Mbps. The computer network must be able to handle the peak volume of data traffic during school time. The file storage server must be able to store more than 100Tb of data. The database server must able to store present, past and future students and all staff particulars information. Table 2.4 - Non-Functional Requirements Documentation Req ID S01 S02 S03 Requirement Description The past student particulars would be converted from the old database to the new database system. All data before the implementation of the computer network will be archived. The old system would be dismantling. The computer network's equipments includes of routers, switches S04 and connecting cable infrastructure would be support and maintained by third party. S05 S06 S07 S08 S09 S10 The computer hardware would support and maintained internally. The computer network would have monthly preventive maintenance. The computer network defect and small enhancements will be addressed on a monthly basis. The computer network applications would be updated every three months. The computer network equipments would follow the approval process to reboot. Login information would be retain for one year and archive every months. ICT499 CAPSTONE PROJECT REPORT 94 S11 Data stored in the file storage server would be retain for one year and archive every months. S12 IT administrators would perform the preventive maintenance. S13 IT administrator would perform the monthly backup required. S14 S15 IT administrator would address the small problems or defects weekly. Tracking log information must be printable in a presentable form. Table 2.5 - System Requirements Documentation Req ID I01 I02 I03 Requirement Description The admin staff would be able to retrieve student information from the student particular database. The teacher would be able to retrieve teaching material from the file storage server. The teacher would be able to save the exam paper in the school storage system. I04 The users would access the internet using the web browser. I05 The users would access the e-mail using the web browser. I06 IT administrator would access the routers and switches using the command prompt. I07 The servers would run on Windows 2007 server. I08 The PCs would run on Windows 7. I09 Firefox 4.0 web browser would be utilized. I10 MySQL would be use to amend the school database. I11 I12 I13 Server must utilize 128-bit SSL certificates to ensure encryption of users browser session. Users must utilize encryption mechanism to login to system. Single sign-on capability would be enabled through integration for internal users. Table 2.6 - Infrastructure Requirements Documentation ICT499 CAPSTONE PROJECT REPORT 95 Appendix B IP Addressing Scheme Number of Host Address Required Network Address Subnet Mask 223 192.168.0.0 255.255.255.0 175 192.168.1.0 255.255.255.0 174 192.168.2.0 255.255.255.0 60 192.168.3.0 255.255.255.128 5 192.168.3.128 255.255.255.224 28 192.168.3.160 255.255.255.224 2 10.0.0.0 255.255.255.0 2 172.0.0.0 2 200.200.1.0 Table 4.1 - Simulation model IP addressing scheme table ICT499 CAPSTONE PROJECT REPORT Used/Available Max No. of Host Available Network Name 254 Class Vlan 254 Lab Vlan 254 Wireless Vlan 127 Staff Vlan 31 Server Vlan 31 IT Administrator Vlan -- -- Link router0 and ISP 255.255.255.0 -- -- Link router1 and ISP 255.255.255.0 -- -- Link ISP and HTTP 223 Used 21 available 175 Used 79 available 174 Used 80 available 60 Used 67 available 5 Used 26 available 28Used 3 available 96 Router Interface Scheme Router name - Router0 Description DTE DCE Network Name And Purpose (If application) S0/0/1 Link between DTE Link router0 and ISP Router0 and ISP F 0/0.1 Link between -Class Vlan Router0 and Switch0 F 0/0.2 Link between -Lab Vlan Router0 and Switch0 F 0/0.3 Link between -Wireless Vlan Router0 and Switch0 F 0/0.4 Link between -Staff Vlan Router0 and Switch0 F 0/0.5 Link between -Server Vlan Router0 and Switch0 F 0/0.6 Link between -IT Administrator Vlan Router0 and Switch0 Table 4.2 - Simulation model Router0 IP addressing table ICT499 CAPSTONE PROJECT REPORT Network Number 10.0.0.0 Interface IP address Subnet Mask MASK 10.0.0.1 255.255.255.0 /24 192.168.0.0 192.168.0.1 255.255.255.0 /24 192.168.1.0 192.168.1.1 255.255.255.0 /24 192.168.2.0 192.168.2.1 255.255.255.0 /24 192.168.3.0 192.168.3.1 255.255.255.128 /25 192.168.3.0 192.168.3.129 255.255.255.224 /27 192.168.3.0 192.168.3.161 255.255.255.224 /27 97 Router name - Router1 Description DTE DCE Network Name And Purpose (If application) S0/0/1 Link between DTE Link router0 and ISP Router1 and ISP F 0/0.1 Link between -Class Vlan Router1 and Switch1 F 0/0.2 Link between -Lab Vlan Router1 and Switch1 F 0/0.3 Link between -Wireless Vlan Router1 and Switch1 F 0/0.4 Link between -Staff Vlan Router1 and Switch1 F 0/0.5 Link between -Server Vlan Router1 and Switch1 F 0/0.6 Link between -IT Administrator Vlan Router1 and Switch1 Table 4.2 - Simulation model Router1 IP addressing table Router name - ISP ICT499 CAPSTONE PROJECT REPORT Network Number 172.0.0.0 Interface IP address Subnet Mask MASK 172.0.0.1 255.255.255.0 /24 192.168.0.0 192.168.0.1 255.255.255.0 /24 192.168.1.0 192.168.1.1 255.255.255.0 /24 192.168.2.0 192.168.2.1 255.255.255.0 /24 192.168.3.0 192.168.3.1 255.255.255.128 /25 192.168.3.0 192.168.3.129 255.255.255.224 /27 192.168.3.0 192.168.3.161 255.255.255.224 /27 98 Description DTE DCE And Purpose (If application) S2/0 Link between DTE Router0 and ISP S3/0 Link between DTE Router1 and ISP F 0/0 Link between -ISP and HTTP Table 4.2 - Simulation model ISP IP addressing table Switch Interface Scheme ICT499 CAPSTONE PROJECT REPORT Network Name Interface IP address Subnet Mask MASK Link router0 and ISP Network Number 10.0.0.0 10.0.0.1 255.255.255.0 /24 Link router1 and ISP 172.0.0.0 172.0.0.1 255.255.255.0 /24 Link ISP and HTTP 200.200.1.0 200.200.1.1 255.255.255.0 /24 99 Switch name - switch0 Description Speed Duplex And Purpose f 0/1 Trunk port to Router0 Auto Full f 0/2 Reserved --f 0/3 Trunk port to Lab1 Switch Auto Full f 0/4 Trunk port to Lab2 Switch Auto Full f 0/5 Trunk port to Lab3 Switch Auto Full f 0/6 Trunk port to Class21 Switch Auto Full f 0/7 Trunk port to Class22 Switch Auto Full f 0/8 Trunk port to Staff2 Switch Auto Full f 0/9 Trunk port to Class31 Switch Auto Full f 0/10 Trunk port to Class32 Switch Auto Full f 0/11 Trunk port to Class33 Switch Auto Full f 0/12 Trunk port to Lab4 Switch Auto Full f 0/13 Trunk port to Lab5 Switch Auto Full f 0/14 Trunk port to Staff3 Switch Auto Full f 0/15 Trunk port to Lab1-2 Switch Auto Full f 0/16 Trunk port to Lab2-2 Switch Auto Full f 0/17 Trunk port to Lab3-2 Switch Auto Full f 0/18 Trunk port to Staff2-2 Switch Auto Full f 0/19 Trunk port to Lab5-2 Switch Auto Full f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Gig1/1 Trunk port to Switch1 Auto Full Table 4.2 - Simulation model Switch0 IP addressing table Network Name Network Subnet Mask VLAN -------------------------- -------------------------- -------------------------- -------------------------- Switch port type Trunk -Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk -----Trunk Switch name - switch1 Description ICT499 CAPSTONE PROJECT REPORT Speed Duplex Network Name Network Subnet Mask VLAN Switch 100 And Purpose f 0/1 Trunk port to Router1 Auto Full f 0/2 Reserved --f 0/3 Trunk port to Server1 Switch Auto Full f 0/4 Trunk port to Class11 Switch Auto Full f 0/5 Trunk port to Class12 Switch Auto Full f 0/6 Trunk port to Class41 Switch Auto Full f 0/7 Trunk port to Class42 Switch Auto Full f 0/8 Trunk port to Class43Switch Auto Full f 0/9 Trunk port to Class44 Switch Auto Full f 0/10 Trunk port to Wireless Point Auto Full Switch f 0/11 Trunk port to Staff1 Switch Auto Full f 0/12 Access port for Vlan 7 Auto Full f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Gig1/1 Trunk port to Switch1 Auto Full Table 4.2 - Simulation model Switch1 IP addressing table ----------- ----------- ----------- ----------- port type Trunk -Trunk Trunk Trunk Trunk Trunk Trunk Trunk Trunk -IT administrator Vlan -------------- -192.168.3.160 -------------- -255.255.255.224 -------------- -7 -------------- Trunk Access ------------Trunk Switch name - Lab1 Description ICT499 CAPSTONE PROJECT REPORT Speed Duplex Network Name Network Subnet Mask VLAN Switch 101 And Purpose f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 3 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Access port for Vlan 3 Auto Full f 0/21 Access port for Vlan 3 Auto Full f 0/22 Access port for Vlan 3 Auto Full f 0/23 Access port for Vlan 3 Auto Full f 0/24 Access port for Vlan 3 Auto Full Table 4.2 - Simulation model lab1 switch IP addressing table Switch name - Lab1-2 ICT499 CAPSTONE PROJECT REPORT -Lab Vlan Class Vlan Class Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan -192.168.1.0 192.168.0.0 192.168.0.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -3 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 port type Trunk Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access 102 Description Speed Duplex And Purpose f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 3 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Access port for Vlan 3 Auto Full f 0/21 Access port for Vlan 3 Auto Full f 0/22 Access port for Vlan 3 Auto Full f 0/23 Access port for Vlan 3 Auto Full f 0/24 Access port for Vlan 3 Auto Full Table 4.2 - Simulation model lab1-2 switch IP addressing table Network Name Network Subnet Mask VLAN -Lab Vlan Class Vlan Class Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan -192.168.1.0 192.168.0.0 192.168.0.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -3 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 Network Name Network Subnet Mask VLAN Switch port type Trunk Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Switch name - Lab2 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex Switch port type 103 f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 3 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Access port for Vlan 3 Auto Full f 0/21 Access port for Vlan 3 Auto Full f 0/22 Access port for Vlan 3 Auto Full f 0/23 Access port for Vlan 3 Auto Full f 0/24 Access port for Vlan 3 Auto Full Table 4.2 - Simulation model lab2 switch IP addressing table -Lab Vlan Class Vlan Class Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan -192.168.1.0 192.168.0.0 192.168.0.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -3 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 Trunk Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Network Name Network Subnet Mask VLAN Switch port type Switch name - Lab2-2 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 104 f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 3 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Access port for Vlan 3 Auto Full f 0/21 Access port for Vlan 3 Auto Full f 0/22 Access port for Vlan 3 Auto Full f 0/23 Access port for Vlan 3 Auto Full f 0/24 Access port for Vlan 3 Auto Full Table 4.2 - Simulation model lab2-2 switch IP addressing table -Lab Vlan Class Vlan Class Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan -192.168.1.0 192.168.0.0 192.168.0.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -3 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 Trunk Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Network Name Network Subnet Mask VLAN Switch port type Switch name - Lab3 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 105 f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 3 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Access port for Vlan 3 Auto Full f 0/21 Access port for Vlan 3 Auto Full f 0/22 Access port for Vlan 3 Auto Full f 0/23 Access port for Vlan 3 Auto Full f 0/24 Access port for Vlan 3 Auto Full Table 4.2 - Simulation model lab3 switch IP addressing table -Lab Vlan Class Vlan Class Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan -192.168.1.0 192.168.0.0 192.168.0.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -3 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 Trunk Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Network Name Network Subnet Mask VLAN Switch port type Switch name - Lab3-2 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 106 f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 3 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Access port for Vlan 3 Auto Full f 0/21 Access port for Vlan 3 Auto Full f 0/22 Access port for Vlan 3 Auto Full f 0/23 Access port for Vlan 3 Auto Full f 0/24 Access port for Vlan 3 Auto Full Table 4.2 - Simulation model lab3-2 switch IP addressing table -Lab Vlan Class Vlan Class Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan -192.168.1.0 192.168.0.0 192.168.0.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -3 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 Trunk Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Network Name Network Subnet Mask VLAN Switch port type Switch name - Class21 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 107 f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class21 switch IP addressing table -Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- -192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- -2 2 2 2 2 2 2 2 ---------------- Trunk Access Access Access Access Access Access Access Access ---------------- Network Name Network Subnet Mask VLAN Switch port type Switch name - Class22 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 108 f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Access port for Vlan 2 Auto Full f 0/11 Access port for Vlan 2 Auto Full f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class22 switch IP addressing table -Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan -------------- -192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 -------------- -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -------------- -2 2 2 2 2 2 2 2 2 2 -------------- Trunk Access Access Access Access Access Access Access Access Access Access -------------- Network Name Network Subnet Mask VLAN Switch Switch name - Staff2 Description ICT499 CAPSTONE PROJECT REPORT Speed Duplex 109 And Purpose f 0/1 Trunk port to Switch0 Auto Full f 0/2 Access port for Vlan 5 Auto Full f 0/3 Access port for Vlan 5 Auto Full f 0/4 Access port for Vlan 5 Auto Full f 0/5 Access port for Vlan 5 Auto Full f 0/6 Access port for Vlan 5 Auto Full f 0/7 Access port for Vlan 5 Auto Full f 0/8 Access port for Vlan 5 Auto Full f 0/9 Access port for Vlan 5 Auto Full f 0/10 Access port for Vlan 5 Auto Full f 0/11 Access port for Vlan 5 Auto Full f 0/12 Access port for Vlan 5 Auto Full f 0/13 Access port for Vlan 5 Auto Full f 0/14 Access port for Vlan 5 Auto Full f 0/15 Access port for Vlan 5 Auto Full f 0/16 Access port for Vlan 5 Auto Full f 0/17 Access port for Vlan 5 Auto Full f 0/18 Access port for Vlan 5 Auto Full f 0/19 Access port for Vlan 5 Auto Full f 0/20 Access port for Vlan 5 Auto Full f 0/21 Access port for Vlan 5 Auto Full f 0/22 Access port for Vlan 5 Auto Full f 0/23 Access port for Vlan 5 Auto Full f 0/24 Access port for Vlan 5 Auto Full Table 4.2 - Simulation model Staff2 switch IP addressing table -Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan -192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 -255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 -5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- port type Trunk Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Switch name - Staff2-2 f 0/1 Description And Purpose Trunk port to Switch0 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 110 f 0/2 Access port for Vlan 5 Auto Full f 0/3 Access port for Vlan 5 Auto Full f 0/4 Access port for Vlan 5 Auto Full f 0/5 Access port for Vlan 5 Auto Full f 0/6 Access port for Vlan 5 Auto Full f 0/7 Access port for Vlan 5 Auto Full f 0/8 Access port for Vlan 5 Auto Full f 0/9 Access port for Vlan 5 Auto Full f 0/10 Access port for Vlan 5 Auto Full f 0/11 Access port for Vlan 5 Auto Full f 0/12 Access port for Vlan 5 Auto Full f 0/13 Access port for Vlan 5 Auto Full f 0/14 Access port for Vlan 5 Auto Full f 0/15 Access port for Vlan 5 Auto Full f 0/16 Access port for Vlan 5 Auto Full f 0/17 Access port for Vlan 5 Auto Full f 0/18 Access port for Vlan 5 Auto Full f 0/19 Access port for Vlan 5 Auto Full f 0/20 Access port for Vlan 5 Auto Full f 0/21 Access port for Vlan 5 Auto Full f 0/22 Access port for Vlan 5 Auto Full f 0/23 Access port for Vlan 5 Auto Full f 0/24 Access port for Vlan 5 Auto Full Table 4.2 - Simulation model Staff2-2 switch IP addressing table Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 5 Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Switch name - Class31 f 0/1 Description And Purpose Trunk port to Switch0 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 111 f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class31 switch IP addressing table Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- 2 2 2 2 2 2 2 2 ---------------- Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- Access Access Access Access Access Access Access Access ---------------- Switch name - Class32 f 0/1 Description And Purpose Trunk port to Switch0 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 112 f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class32 switch IP addressing table Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- 2 2 2 2 2 2 2 2 ---------------- Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- Access Access Access Access Access Access Access Access ---------------- Switch name - Class33 f 0/1 Description And Purpose Trunk port to Switch0 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 113 f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class33 switch IP addressing table Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- 2 2 2 2 2 2 2 2 ---------------- Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- Access Access Access Access Access Access Access Access ---------------- Switch name - Lab4 f 0/1 Description And Purpose Trunk port to Switch0 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 114 f 0/2 Access port for Vlan 3 Auto Full f 0/3 Access port for Vlan 3 Auto Full f 0/4 Access port for Vlan 3 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Reserved --f 0/9 Reserved --f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Lab4 switch IP addressing table Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan ------------------ 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 ------------------ 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ------------------ 3 3 3 3 3 3 ------------------ Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- Access Access Access Access Access Access ------------------ Switch name - Lab5 f 0/1 Description And Purpose Trunk port to Switch0 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 115 f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 3 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Access port for Vlan 3 Auto Full f 0/21 Access port for Vlan 3 Auto Full f 0/22 Access port for Vlan 3 Auto Full f 0/23 Access port for Vlan 3 Auto Full f 0/24 Reserved --Table 4.2 - Simulation model Lab5 switch IP addressing table Class Vlan Class Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan -- 192.168.0.0 192.168.0.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 -- 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -- 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 -- Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access -- Switch name - Lab5-2 f 0/1 Description And Purpose Trunk port to Switch0 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 116 f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 3 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Access port for Vlan 3 Auto Full f 0/21 Access port for Vlan 3 Auto Full f 0/22 Access port for Vlan 3 Auto Full f 0/23 Access port for Vlan 3 Auto Full f 0/24 Reserved --Table 4.2 - Simulation model Lab5-2 switch IP addressing table Class Vlan Class Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan -- 192.168.0.0 192.168.0.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 -- 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 -- 2 2 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 -- Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access -- Switch name - Staff3 f 0/1 Description And Purpose Trunk port to Switch0 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 117 f 0/2 Access port for Vlan 5 Auto Full f 0/3 Access port for Vlan 5 Auto Full f 0/4 Access port for Vlan 3 Auto Full f 0/5 Access port for Vlan 3 Auto Full f 0/6 Access port for Vlan 3 Auto Full f 0/7 Access port for Vlan 3 Auto Full f 0/8 Access port for Vlan 3 Auto Full f 0/9 Access port for Vlan 3 Auto Full f 0/10 Access port for Vlan 3 Auto Full f 0/11 Access port for Vlan 3 Auto Full f 0/12 Access port for Vlan 3 Auto Full f 0/13 Access port for Vlan 3 Auto Full f 0/14 Access port for Vlan 3 Auto Full f 0/15 Access port for Vlan 3 Auto Full f 0/16 Access port for Vlan 3 Auto Full f 0/17 Access port for Vlan 3 Auto Full f 0/18 Access port for Vlan 3 Auto Full f 0/19 Access port for Vlan 3 Auto Full f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Staff3 switch IP addressing table Staff Vlan Staff Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan Lab Vlan ------ 192.168.3.0 192.168.3.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 192.168.1.0 ------ 255.255.255.128 255.255.255.128 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ------ 5 5 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 3 ------ Speed Duplex Network Name Network Subnet Mask VLAN Auto -- -- -- -- Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access ------ Switch name - Wireless f 0/1 Description And Purpose Trunk port to Switch1 ICT499 CAPSTONE PROJECT REPORT Full Switch port type Trunk 118 f 0/2 Access port for Vlan 4 Auto Full Wireless Vlan f 0/3 Access port for Vlan 2 Auto Full Class Vlan f 0/4 Reserved ---f 0/5 Reserved ---f 0/6 Reserved ---f 0/7 Reserved ---f 0/8 Reserved ---f 0/9 Reserved ---f 0/10 Reserved ---f 0/11 Reserved ---f 0/12 Reserved ---f 0/13 Reserved ---f 0/14 Reserved ---f 0/15 Reserved ---f 0/16 Reserved ---f 0/17 Reserved ---f 0/18 Reserved ---f 0/19 Reserved ---f 0/20 Reserved ---f 0/21 Reserved ---f 0/22 Reserved ---f 0/23 Reserved ---f 0/24 Reserved ---Table 4.2 - Simulation model Wireless switch IP addressing table 192.168.2.0 192.168.0.0 ---------------------- 255.255.255.0 255.255.255.0 ---------------------- 4 2 ---------------------- Access Access ---------------------- Network Subnet Mask VLAN Switch port type Switch name - Server1 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex Network Name 119 f 0/1 Trunk port to Switch1 Auto Full f 0/2 Access port for Vlan 6 Auto Full f 0/3 Access port for Vlan 6 Auto Full f 0/4 Access port for Vlan 6 Auto Full f 0/5 Access port for Vlan 6 Auto Full f 0/6 Access port for Vlan 6 Auto Full f 0/7 Reserved --f 0/8 Reserved --f 0/9 Reserved --f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Server1 switch IP addressing table -Wireless Vlan Class Vlan Wireless Vlan Class Vlan Wireless Vlan ------------------- -192.168.3.128 192.168.3.128 192.168.3.128 192.168.3.128 192.168.3.128 ------------------- -255.255.255.224 255.255.255.224 255.255.255.224 255.255.255.224 255.255.255.224 ------------------- -6 6 6 6 6 ------------------- Trunk Access Access Access Access Access ------------------- Network Name Network Subnet Mask VLAN Switch port type Switch name - Class11 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 120 f 0/1 Trunk port to Switch1 Auto Full f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class11 switch IP addressing table -Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- -192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- -2 2 2 2 2 2 2 2 ---------------- Trunk Access Access Access Access Access Access Access Access ---------------- Network Name Network Subnet Mask VLAN Switch port type Switch name - Class12 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 121 f 0/1 Trunk port to Switch1 Auto Full f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class12switch IP addressing table -Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- -192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- -2 2 2 2 2 2 2 2 ---------------- Trunk Access Access Access Access Access Access Access Access ---------------- Network Name Network Subnet Mask VLAN Switch port type Switch name - Staff1 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 122 f 0/1 Trunk port to Switch1 Auto Full f 0/2 Access port for Vlan 5 Auto Full f 0/3 Access port for Vlan 5 Auto Full f 0/4 Access port for Vlan 5 Auto Full f 0/5 Access port for Vlan 5 Auto Full f 0/6 Access port for Vlan 5 Auto Full f 0/7 Access port for Vlan 5 Auto Full f 0/8 Reserved --f 0/9 Reserved --f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Staff1 switch IP addressing table -Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan Staff Vlan ------------------ -192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 192.168.3.0 ------------------ -255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 255.255.255.128 ------------------ -5 5 5 5 5 5 ------------------ Trunk Access Access Access Access Access Access ------------------ Network Name Network Subnet Mask VLAN Switch port type Switch name - Class41 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 123 f 0/1 Trunk port to Switch1 Auto Full f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class41 switch IP addressing table -Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- -192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- -2 2 2 2 2 2 2 2 ---------------- Trunk Access Access Access Access Access Access Access Access ---------------- Network Name Network Subnet Mask VLAN Switch port type Switch name - Class42 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 124 f 0/1 Trunk port to Switch1 Auto Full f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class42 switch IP addressing table -Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- -192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- -2 2 2 2 2 2 2 2 ---------------- Trunk Access Access Access Access Access Access Access Access ---------------- Network Name Network Subnet Mask VLAN Switch port type Switch name - Class43 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 125 f 0/1 Trunk port to Switch1 Auto Full f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Reserved --f 0/11 Reserved --f 0/12 Reserved --f 0/13 Reserved --f 0/14 Reserved --f 0/15 Reserved --f 0/16 Reserved --f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class43 switch IP addressing table -Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan ---------------- -192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 ---------------- -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 ---------------- -2 2 2 2 2 2 2 2 ---------------- Trunk Access Access Access Access Access Access Access Access ---------------- Network Name Network Subnet Mask VLAN Switch port type Switch name - Class44 Description And Purpose ICT499 CAPSTONE PROJECT REPORT Speed Duplex 126 f 0/1 Trunk port to Switch1 Auto Full f 0/2 Access port for Vlan 2 Auto Full f 0/3 Access port for Vlan 2 Auto Full f 0/4 Access port for Vlan 2 Auto Full f 0/5 Access port for Vlan 2 Auto Full f 0/6 Access port for Vlan 2 Auto Full f 0/7 Access port for Vlan 2 Auto Full f 0/8 Access port for Vlan 2 Auto Full f 0/9 Access port for Vlan 2 Auto Full f 0/10 Access port for Vlan 2 Auto Full f 0/11 Access port for Vlan 2 Auto Full f 0/12 Access port for Vlan 2 Auto Full f 0/13 Access port for Vlan 2 Auto Full f 0/14 Access port for Vlan 2 Auto Full f 0/15 Access port for Vlan 4 Auto Full f 0/16 Access port for Vlan 4 Auto Full f 0/17 Reserved --f 0/18 Reserved --f 0/19 Reserved --f 0/20 Reserved --f 0/21 Reserved --f 0/22 Reserved --f 0/23 Reserved --f 0/24 Reserved --Table 4.2 - Simulation model Class44 switch IP addressing table ICT499 CAPSTONE PROJECT REPORT -Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Class Vlan Wireless Vlan Wireless Vlan --------- -192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.0.0 192.168.2.0 192.168.2.0 --------- -255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 255.255.255.0 --------- -2 2 2 2 2 2 2 2 2 2 2 2 2 4 4 --------- Trunk Access Access Access Access Access Access Access Access Access Access Access Access Access Access Access --------- 127 Appendix C Simulation Model configuration Router0 Configuration version 12.4 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname Router1 ! enable secret 5 $1$mERr$G2PSu4QGw/5shgwTGTGH6/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/0 no ip address duplex auto speed auto shutdown ! interface FastEthernet0/0.1 encapsulation dot1Q 2 ip address 192.168.0.1 255.255.255.0 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.2 encapsulation dot1Q 3 ip address 192.168.1.1 255.255.255.0 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.3 encapsulation dot1Q 4 ip address 192.168.2.1 255.255.255.0 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.4 encapsulation dot1Q 5 ip address 192.168.3.1 255.255.255.128 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.5 encapsulation dot1Q 6 ip address 192.168.3.129 255.255.255.224 ip helper-address 192.168.3.133 ! ICT499 CAPSTONE PROJECT REPORT 128 interface FastEthernet0/0.6 encapsulation dot1Q 7 ip address 192.168.3.161 255.255.255.224 ip helper-address 192.168.3.133 ! interface Serial0/0/1 bandwidth 64 ip address 10.0.0.1 255.255.255.0 ip access-group 101 out ! router rip ! ip classless ip route 0.0.0.0 0.0.0.0 10.0.0.2 ! access-list 101 permit icmp any any access-list 101 permit tcp 192.168.1.0 0.0.0.255 any access-list 101 permit tcp 192.168.2.0 0.0.0.255 any access-list 101 permit tcp 192.168.3.0 0.0.0.255 any access-list 101 deny ip any any access-list 50 permit host 192.168.3.162 ! no cdp run ! line con 0 exec-timeout 0 0 login local line vty 0 4 access-class 50 in login local transport output telnet ! end ICT499 CAPSTONE PROJECT REPORT 129 Router1 Configuration version 12.4 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname Router1 ! enable secret 5 $1$mERr$G2PSu4QGw/5shgwTGTGH6/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/0 no ip address duplex auto speed auto ! interface FastEthernet0/0.1 encapsulation dot1Q 2 ip address 192.168.0.1 255.255.255.0 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.2 encapsulation dot1Q 3 ip address 192.168.1.1 255.255.255.0 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.3 encapsulation dot1Q 4 ip address 192.168.2.1 255.255.255.0 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.4 encapsulation dot1Q 5 ip address 192.168.3.1 255.255.255.128 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.5 encapsulation dot1Q 6 ip address 192.168.3.129 255.255.255.224 ip helper-address 192.168.3.133 ! interface FastEthernet0/0.6 encapsulation dot1Q 7 ip address 192.168.3.161 255.255.255.224 ip helper-address 192.168.3.133 ! interface Serial0/0/1 ICT499 CAPSTONE PROJECT REPORT 130 bandwidth 64 ip address 172.0.0.1 255.255.255.0 ip access-group 101 out ! router rip ! ip classless ip route 0.0.0.0 0.0.0.0 172.0.0.2 ! access-list 101 permit icmp any any access-list 101 permit tcp 192.168.1.0 0.0.0.255 any access-list 101 permit tcp 192.168.2.0 0.0.0.255 any access-list 101 permit tcp 192.168.3.0 0.0.0.255 any access-list 101 deny ip any any access-list 50 permit host 192.168.3.162 ! no cdp run ! line con 0 exec-timeout 0 0 login local line vty 0 4 access-class 50 in login local transport output telnet ! end ICT499 CAPSTONE PROJECT REPORT 131 ISP Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname Router ! interface FastEthernet0/0 ip address 200.200.1.1 255.255.255.0 duplex auto speed auto ! interface Serial2/0 ip address 10.0.0.2 255.255.255.0 ! interface Serial3/0 ip address 172.0.0.2 255.255.255.0 clock rate 64000 ! ip classless ip route 0.0.0.0 0.0.0.0 172.0.0.1 ip route 0.0.0.0 0.0.0.0 10.0.0.1 20 ! line con 0 line vty 0 4 login ! end ICT499 CAPSTONE PROJECT REPORT 132 Switch0 Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname Switch0 ! enable password siyuan ! username siyuan password 0 siyuan ! spanning-tree portfast default ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 ! interface FastEthernet0/3 switchport access vlan 3 ! interface FastEthernet0/4 switchport access vlan 3 ! interface FastEthernet0/5 switchport access vlan 3 ! interface FastEthernet0/6 switchport access vlan 2 switchport mode trunk ! interface FastEthernet0/7 switchport access vlan 2 switchport mode trunk ! interface FastEthernet0/8 switchport access vlan 5 switchport mode trunk ! interface FastEthernet0/9 switchport access vlan 2 switchport mode trunk ! interface FastEthernet0/10 switchport access vlan 2 switchport mode trunk ! interface FastEthernet0/11 ICT499 CAPSTONE PROJECT REPORT 133 switchport access vlan 2 switchport mode trunk ! interface FastEthernet0/12 switchport access vlan 3 switchport mode trunk ! interface FastEthernet0/13 switchport access vlan 3 switchport mode trunk ! interface FastEthernet0/14 switchport access vlan 5 switchport mode trunk ! interface GigabitEthernet1/1 switchport mode trunk ! interface Vlan7 ip address 192.168.3.164 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 134 Switch1 Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname Switch1 ! enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 ! interface FastEthernet0/3 switchport access vlan 6 switchport mode trunk ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface FastEthernet0/6 switchport access vlan 2 ! interface FastEthernet0/7 switchport access vlan 2 ! interface FastEthernet0/8 switchport access vlan 2 ! interface FastEthernet0/9 switchport access vlan 2 ! interface FastEthernet0/10 switchport access vlan 4 switchport mode trunk ! interface FastEthernet0/11 switchport access vlan 5 switchport mode trunk ! interface FastEthernet0/12 switchport access vlan 7 ICT499 CAPSTONE PROJECT REPORT 135 ! interface GigabitEthernet1/1 switchport mode trunk ! interface Vlan7 ip address 192.168.3.165 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 136 Lab1 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Lab1 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 3 ! interface FastEthernet0/3 switchport access vlan 2 ! Vlan7 ip address 192.168.3.166 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 password siyuan login local exec-timeout 0 0 ! line vty 0 4 access-class 50 in password siyuan login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 137 Lab2 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Lab2 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 3 ! interface FastEthernet0/3 switchport access vlan 2 ! Vlan7 ip address 192.168.3.166 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 password siyuan login local exec-timeout 0 0 ! line vty 0 4 access-class 50 in password siyuan login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 138 Lab3 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Lab3 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 3 ! interface FastEthernet0/3 switchport access vlan 2 ! Vlan7 ip address 192.168.3.166 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 password siyuan login local exec-timeout 0 0 ! line vty 0 4 access-class 50 in password siyuan login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 139 Class21 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 21 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.169 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 140 Class22 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 22 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface FastEthernet0/6 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.170 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 141 Staff2 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Staff 2 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 5 ! interface FastEthernet0/3 switchport access vlan 5 ! interface FastEthernet0/4 switchport access vlan 5 ! interface FastEthernet0/5 switchport access vlan 5 ! interface Vlan7 ip address 192.168.3.171 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 142 Class31 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 31 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface FastEthernet0/6 switchport access vlan 5 ! interface FastEthernet0/7 switchport access vlan 5 ! interface FastEthernet0/8 switchport access vlan 5 ! interface FastEthernet0/9 switchport access vlan 5 ! interface Vlan7 ip address 192.168.3.172 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local ICT499 CAPSTONE PROJECT REPORT 143 transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 144 Class32 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 32 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.169 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 145 Class33 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 33 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.169 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 146 Lab4 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Lab 4 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 3 ! interface FastEthernet0/3 switchport access vlan 3 ! interface FastEthernet0/4 switchport access vlan 3 ! interface Vlan7 ip address 192.168.3.175 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 147 Lab5 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Lab 5 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 3 ! interface FastEthernet0/5 switchport access vlan 3 ! interface Vlan7 ip address 192.168.3.176 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 148 Staff3 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Staff 3 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 5 ! interface FastEthernet0/3 switchport access vlan 3 ! interface Vlan7 ip address 192.168.3.177 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 149 Wireless Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Wireless 1 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 4 ! interface FastEthernet0/3 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.185 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 150 Server1 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Server 1 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 6 ! interface FastEthernet0/3 switchport access vlan 6 ! interface FastEthernet0/4 switchport access vlan 6 ! interface FastEthernet0/5 switchport access vlan 6 ! interface FastEthernet0/6 switchport access vlan 6 ! interface Vlan7 ip address 192.168.3.184 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 151 Class11 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 11 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.169 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 152 Class12 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 12 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.169 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 153 Staff1 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Staff 1 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 5 ! interface FastEthernet0/3 switchport access vlan 5 ! interface FastEthernet0/4 switchport access vlan 5 ! interface Vlan7 ip address 192.168.3.182 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 154 Class41 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 41 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.169 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 155 Class42 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 42 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.169 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 156 Class43 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 43 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface Vlan7 ip address 192.168.3.169 255.255.255.224 ! access-list 50 permit host 192.168.3.162 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 157 Class44 Switch Configuration version 12.2 no service timestamps log datetime msec no service timestamps debug datetime msec no service password-encryption ! hostname "Class 44 Switch" ! enable secret 5 $1$mERr$MutzkfG9Rb/hsvxae6ATo/ enable password siyuan ! username siyuan password 0 siyuan ! interface FastEthernet0/1 switchport mode trunk ! interface FastEthernet0/2 switchport access vlan 2 ! interface FastEthernet0/3 switchport access vlan 2 ! interface FastEthernet0/4 switchport access vlan 2 ! interface FastEthernet0/5 switchport access vlan 2 ! interface FastEthernet0/6 switchport access vlan 2 ! interface FastEthernet0/7 switchport access vlan 2 ! interface FastEthernet0/8 switchport access vlan 2 ! interface FastEthernet0/9 switchport access vlan 2 ! interface FastEthernet0/10 switchport access vlan 4 ! interface FastEthernet0/11 switchport access vlan 4 ! interface Vlan7 ip address 192.168.3.178 255.255.255.224 ! access-list 50 permit host 192.168.3.162 ICT499 CAPSTONE PROJECT REPORT 158 line con 0 login local ! line vty 0 4 access-class 50 in login local transport output telnet line vty 5 15 login ! end ICT499 CAPSTONE PROJECT REPORT 159 Simulation Model Passwords & WEP Key Router0 Username - siyuan password - siyuan Enable - fyp Username - siyuan password - siyuan Enable - fyp Username - siyuan password - siyuan Enable - siyuan Username - siyuan password - siyuan Enable - siyuan Username - siyuan password - siyuan Enable - siyuan 1234567891 Router1 Switch0 Switch1 All Switches WEP Key ICT499 CAPSTONE PROJECT REPORT 160 Floor Map of simulation model ICT499 CAPSTONE PROJECT REPORT 161 ICT499 CAPSTONE PROJECT REPORT 162 Appendix D ICMP connection between Vlan: From To Result (Pass/Fail) Vlan 2 Vlan 2 Pass Vlan 2 Vlan 3 Pass Vlan 2 Vlan 4 Pass Vlan 2 Vlan 5 Pass Vlan 2 Vlan 6 Pass Vlan 2 Vlan 7 Vlan 3 Vlan 2 Pass Pass Vlan 3 Vlan 3 Pass Vlan 3 Vlan 4 Pass Vlan 3 Vlan 5 Pass Vlan 3 Vlan 6 Pass Vlan 3 Vlan 7 Vlan 4 Vlan 2 Pass Pass Vlan 4 Vlan 3 Pass Vlan 4 Vlan 4 Pass Vlan 4 Vlan 5 Pass Vlan 4 Vlan 6 Pass Vlan 4 Vlan 7 Vlan 5 Vlan 2 Pass Pass Vlan 5 Vlan 3 Pass Vlan 5 Vlan 4 Pass Vlan 5 Vlan 5 Pass Vlan 5 Vlan 6 Pass Vlan 5 Vlan 7 Vlan 6 Vlan 2 Pass Pass Vlan 6 Vlan 3 Pass Vlan 6 Vlan 4 Pass Vlan 6 Vlan 5 Pass Vlan 6 Vlan 6 Pass ICT499 CAPSTONE PROJECT REPORT 163 Vlan 6 Vlan 7 Vlan 7 Vlan 2 Pass Pass Vlan 7 Vlan 3 Pass Vlan 7 Vlan 4 Pass Vlan 7 Vlan 5 Pass Vlan 7 Vlan 6 Pass Vlan 7 Vlan 7 Pass DHCP connectivity: All facilities connected to the network are able to get the dynamic address from the DHCP server. Result was illustrated using the simulation presentation. Vlan connectivity to the HTTP server: From To Result (Pass/Fail) Vlan 2 HTTP Pass (Not able to access) Vlan 3 HTTP Pass Vlan 4 HTTP Pass Vlan 5 HTTP Pass Vlan 6 HTTP Pass (Not able to access) Vlan 7 HTTP Pass Telnet results to all routers and switches from the IT admin PC: From To Result (Pass/Fail) IT admin PC Router0 Pass IT admin PC Router1 Pass IT admin PC Switch0 Pass IT admin PC Switch1 Pass IT admin PC Lab 1 Pass IT admin PC Lab 2 Pass IT admin PC Lab 3 Pass IT admin PC Class 21 Pass IT admin PC Class 22 Pass ICT499 CAPSTONE PROJECT REPORT 164 IT admin PC Staff 2 Pass IT admin PC Class 31 Pass IT admin PC Class 32 Pass IT admin PC Class 33 Pass IT admin PC Lab 4 Pass IT admin PC Lab 5 Pass IT admin PC Staff 3 Pass IT admin PC Class 41 Pass IT admin PC Class 42 Pass IT admin PC Class 43 Pass IT admin PC Class 44 Pass IT admin PC Class 11 Pass IT admin PC Class 12 Pass IT admin PC Staff 1 Pass IT admin PC Server 1 Pass IT admin PC Wireless Pass User To Result (Pass/Fail) Staff FTP Pass Student FTP Pass cisco FTP Pass FTP connectivity of users: Scenario testing in Packet Tracer simulation mode Scenario Result (Pass/Fail) Scenario 0 Pass Scenario 1 Pass Scenario 2 Pass ICT499 CAPSTONE PROJECT REPORT
