Saturday, December 7, 2019
Sample on Network Tecnologies & Optics Communications
Questions: 1. Discuss the role of networks within different organizations and the resource implications of networks2. Discuss the different distributed computing approaches of peer-to-peer and client-server networks3. Explain the functions of client and server computers on a network and give at least one example of interactions between a client and server computer4. Describe the advantages of client-server approaches particularly over centralized services1. Draw and describe basic network topologies and define basic network components2. Discuss role of software and hardware3. Discuss factors influencing choice of networks stating advantages and disadvantages that arise from different topologies4. Determine a suitable network for a given site1. Explain different connection materials including their specifications and list the criteria you would use to choose such materials2. Describe basic signaling methods and their characteristics3. Explain the role of the network interface card and carry-out selection, installation and configuration of a network interface card using NOS tools4. Identify how the relevant parameters and protocols are set5. Discuss factors that affect the performance of network interface cards6. Determine a cabling and hardware connection configuration for a given site1. present the OSI layered model2. Explain the role of drivers in a network, discussing their relationship to the NOS and OSI model3. Discuss how drivers are selected and implemented for various network components; install NIC driver and demonstrate how to remove and update4. Explain the detailed operation of different IEEE 802.N network configurations5. Refer the 802 protocols to the existing OSI layers6. Relate how architecture influences access and control of the network and draw out merits of different architectures7. Describe scenarios where one architecture might be favored over another1. Discuss the role of packets and how they are built up from their various components, giving an exam ple where data packets are transmitted through different layers of the OSI model2. Discuss the role of protocols at different layers of the OSI model, describing the function of specific protocols3. Explain examples of transmission between different network layers. Answers: Introduction As an IT Consultant, the purpose of this proposal is to present a detail report on the basic networking requirements for the given case study. The new requirements provided by the import export organization are analyzed and accordingly suggestions and solutions are proposed. The report will cover a detail justification of the selected networking topology and other networking components, connection materials and network software and hardware components. Additionally, the proposal meets the criteria for providing the receptionists, order processing and other management staff access to the centralized customer database. Alongside to that, the company Intranet should be accessible from all authorized employees located both in the office as well as in the ware house within ten miles distance (Li, 2014). A detail insight to the role of the network including diagrams, hardware configuration issues and other networking requirement is discussed along with the issues regarding network architec ture and its influence on the overall performance of the organization. Discussion of the role of Networks within the dissimilar organizations and the resources suggestion of networks The function of networks in different organizations can be described as below: Increase employees productivity Reduce equipment costs Ease of access to resources Increase capacity for storage Reduce costs of communication Manage resources and software centrally. Increase rate of installation of software on workstations. Share data or resource with different users. The resource implications of networks involve various factors like dependence of hardware and software. Other than this is the technology for data transmission like routing and switching of the networks. 2. Investigation of Basic Hardware Components and the Role of the Networking Operating System (NOS) Software Drawing and Description of the basic Network Topologies Network Topology The network topology is that topology to understand the systems of any computer network. It describes the way how the computers are linked with one another. The basic network topologies are: Ring, Star, Bus and Mesh topologies. Ring Topology: Each of the nodes is connected to each other in the form of a circle; none of the nodes are opened. The packets are sent around the ring to reach its final destination. It is also known as token ring topology, as it accesses to token as well as transmits the packets. Star Topology: Basically, this type of topology is used in home or office network. The nodes are connected to each other with a central controller that is called hub. If there is any breakdown in the cable, there it cannot hamper the entire system. Bus Topology: It is a good resolution over the ring and bus topologies based on the function that it allows high rate of transmission of data. Mesh Topology: In this network, each of the nodes has no capacity of routing. Therefore, the communication between two nodes is fast. Each of the nodes is connected to one another that allow most broadcast to be disrupted, as any one of its connections fail. There are two types of basic network components that are used to manage the network system. The two components are Hardware components as well as Software components. In the hardware components, it contains network router, switches as well as bridges. The software components are the network operating system. The role of Software and Hardware Network hardware is the components of a system of network that transmits the data as well as facilitates the functions of a computer network. Network software consists of protocols as well as programs to connect the computers for the purpose of sharing the data. It mainly increases the sharing of information. Factors that Influencing choice of networks advantages and disadvantages over topologies The factors are the following of Ring topologies are: It manages the connectivity between the computers at the time when the network server does not work It is a network that access to token as well as the chance to transmit This network is slower than the Ethernet network The interruption of communication is directly virtual to the nodes in the network, and it increases the delay in communication The factors of star topology are: It has least amount of line cost as because only n-lines are needed to connect the n number of nodes Its formatting is simple so it is very easy to expand on this topology One of its disadvantages is that, it is dependent on its hub as well as the entire system of the network depends on the central controller The factors of bus topology are: It is a temporary network that is easy to implement as well as extend It does not manage better with a traffic rate of heavy, therefore it is difficult to administer as well as troubleshoot The factors of Mesh topology are: Each of its nodes have no routing capacity, thus he communication between two nodes is fast It requires more cable than the topologies of LAN, therefore it has problematical operations Determination of suitable network Basically, star network is used for office. This network consists of a central controller that is called hub that can transmit the messages. In this network, every computer work station is connected to the central node. The data are throughout the hub before going to its destination files. The hub is used to control the functions of the network. Relation of architecture influences access and control of the network and draw out merits of different architectures The network architecture influences the cost as well as requirements of adopting new applications. The architecture that enables the network providers to control the applications and the content on their network give the power to shape the information (Schwartz and Stone, 2013). The system of access control refers to the computer based as well as electronic access system. The architecture-related influences both access and control of the network. The architecture is used to access the network in order to provide connecting devices to the network as well as control those devices that are allowed to communicate on the network. The merits of different architectures are (Katugampola et al. 2014): Client server architecture: All the files are stored in the same place, thus the management of the files is easy. The changes within the server are easily made based on upgrading the server. Peer-to-peer architecture: This architecture does not have any central computer server. In this network architecture, each of the workstations has equivalent capabilities as well as responsibilities. This network is simpler than client-server (Rastgar and Shahrokhian, 2014). Description of the Scenario where one architecture might be favored over another The scenario in which architecture is favored over another is For a larger business, with multiple WAN links, add WAN routers. Most of the large business companies work in multiple locations to expand their networks worldwide. Therefore, maintenance of huge networks is the most important parameter (KiranRana and Setia, 2015). Using the internet, the organizations can form a WAN with the shared users irrespective of their geographical locations. It is assumed that a company X is connected with its other branches through the WAN links. It is possible with the connection of single Internet Service Provider, is the usual scenario. When the LAN accesses to the WAN, then the security over the transactions as well as protection of the data becomes a problem as there is a chance of hacking the data and information. It can lead to failure of the network. The link of dual WAN connects the networks for the connection of dual ISP. The purpose of Dual WAN is effective in the current scenario (Koo dziejczyk and Ogiela, 2012). Task 1 Laboratory 1: Network Components 1. Explanation of Different Network Components Twisted-pair cable: Brief description: Twisted-pair cable is simplest form of transmission medium used in telecommunications. Twisted pair cables are constructed with two or more electronic wires that are arranged in a spiral form. To be more specific, two copper wires are twisted where each of them has a plastic or metallic insulation. Functionality: twisted pair cables can support both analog and digital transmission. Shielded cables are mainly used to protect the electronic signals from interference. Twisted pairs that have metal insulation are generally used for short distance data transmission. The speed and performance of the wire is directly proportional to the number of twists in the wire. STP with maximum number of twists can significantly reduce electromagnetic interference, crosstalk and noise in the transmission medium while transmitting either analog or digital signals. It is the least expensive type of data transmission and communication medium and is used mostly by older telephone service providers and Local Area Networks or LANs. Coaxial cable: Brief description: coaxial cables are a common medium used in data communication and transmission. This type of cable consists of a wire or a physical channel that is guided or surrounded by layers of insulation. The inner conductor is surrounded by a braided conductor. The outer layer is a shield that protects the signals from electromagnetic interference. The braided or grounded layer serving as a line has the sheath or jacket for gaining maximum efficiency in transmitting information while carrying lower frequency signals. Functionality: Coaxial cables are more expensive medium than twisted pair cables but they can carry more amount of information with fewer amounts of interferences. Other usages of coaxial cables include LANs or Local Area Networks such as Ethernets; also telephone companies use coaxial cables to carry telephone signals to users telephone poles. Fiber-optic cable: Brief description: Fiber optic or optical fiber cables are typically the most popular and widely used mode of data transmission of modern days. An optical fiber cable consists of multiple fiber optics each with protective plastic coating. More specifically, fiber optic cables have two main layers that are core and cladding. The cladding is coated with protective polyimide. Several layers of protective sheath are added to the fibers depending upon the environment where it will be deployed (Ahmad et al. 2014). Functionality: the optical fiber can carry light. Fiber optics are known mostly for long distance high speed data communication. Modern day fiber optics can have the capacity to carry and transmit data over 50 kilometers or more having bandwidth of about 1 terabyte per second. One of the prominent examples of optical fiber usage is the Internet. Using fiber optic cables data is digitally transmitted over network instead of analogically. Although it costs more than twisted pair or coaxial cables, it much less susceptible to signal interference, can carry significantly huge data in less time and over much longer distances (Beko and Dinis, 2014). Modem: Brief description: A modem or modulator demodulator is a type of hardware device used in computer networking to transmit data over twisted pair or fiber optic cable lines. The term modulator demodulator comes from its ability to transform analog signals into digital signals and vice versa. Computers generally understand information represented in a digital form whereas the transmission mediums carry data in the form of analog waves or frequency. Modems are required as a hardware interface to convert these signals to computer readable form (Bhaskar and Mallick, 2015). Functionality: Modem is used to send and receive data and information between computers connected over telephone lines by transforming digital data into analog signals and transmitting over telephone cable networks. It uses the asynchronous method of transmission where the data are sent in the form of packets (Bhaskar and Mallick, 2015). The receiver modem reassembles the packets and converts it back to its digital form so that the computer can understand. Dial-up modems that were widely used before used to dial up the phone number to establish a communication to connect to the other modem over the Internet. Switch: Brief description: network switches are a type of networking hardware devices that can connect multiple computers over a Local Area Network or Ethernet. Switch can take data from multiple input ports, then by using packet switching it channels the packets to the intended output port and forwards the data to its destination device (Buerschaper, 2014). Functionality: The fundamental functionality of a network switch is to take the information from any input ports connected to it and forward the data packets to the desired destination. Nowadays a number of medium and large size LANs implements single and multilayered switched networks. Additional functions of a switch include verifying the data packets and their header addresses and intelligent routing (Burnstock, 2013). The reason it is called intelligent is because network switches can prevent collision by establishing dedicated link between source and destination ports. 2. Network Interface Card Description of basic signaling methods and their characteristics In telecommunications, the term signaling refers to exchange of data and information between a sender and a receiver over a communication channel in a form of analog signal. The basic forms of signaling can be classified into several groups. In-band signaling: in-band signaling implies exchange of information using the same channel as that of the telephone call. More accurately, the data and control signals are carried over the same line or channel. Out-of-band signaling: More accurately, out-band signaling uses separate channel frequencies for transmitting control signals and data. For instance, ISDN uses its channel D and B for sending control signals and data signals respectively. Common-channel signaling: These type of signaling uses a separate channel for transmitting signaling information for multiple connections. The reason it is called as common channel is all these bearer channels or connection uses the same channel for transmitting signaling information while each has their own separate channel for transmission of data or voice. Associated signaling: Associated signaling uses the signaling technique in which the same network elements help to transmit the information. More specifically, all the signaling and data channels have common network components (Cheong et al. 2014). Channel-associated signaling provides an individual line to transmit signaling information dedicated for every connection or bearer channel. The role of the network interface card Installation procedure of NIC: It is always recommended to unplug the computer before installing NIC to prevent electronic mishaps. The steps which lead to installation of NIC are described below. Open the computer case and locate the PCI or Peripheral Component Interconnect. The PCI slot has to be cleared of the metal plate (Bajwa, Lee and Bordbar, 2012). Take out the NIC card from its anti-static bag and place it onto the PCI slot. It has to be done keeping right alignments with the notches. Give a slight press so that the NIC fits into the PCI slot. Secure the card by screws to hold it in. Close the computer case and turn the power back on. The next steps are to configure the PCs network from Control Panel and check the internet connection (Cheong et al. 2014). Selection and configuration of NIC: The identification and configuration of NIC involves the following steps: Network settings- Local settings - NIC configuration. Network agent uses separate NIC for monitoring and managing the network. Monitor network traffic: After identifying the NIC model, the correct Driver for NIC is located. The NIC supported drivers usually reside in the generic kernel. Under the Monitoring section of network settings, check the box with use this NIC to monitor traffic (Clear, 2014). Change MAC address: Each MAC address uses one IP address. To change the MAC address, specific commands can be run on the DOS prompt to view the address or select override MAC address from the option menu and enter the MAC address. Configuring network card using command prompt displays information such as the loopback address, the Ethernet interfaces. If these are not displayed properly then the NIC is not configured correctly to be able to connect over a network (Ahmad et al. 2014). Identification of the way of relevant parameters and protocols are set The Network Administration tool is used to set various parameters as well as protocols of the network interface configuration files. The configurations parameters are set as shown below (Cui, 2015): BONDING_OPTS= It sets the configuration of its parameters for the device related to bonding. These parameters are identical as well as the module parameters are described in bonding Module Directives. BOOTPROTO= Here the protocol is one of the following: None- none of the boot protocol is used Boot up-the protocol BOOTP is used Dhcp-the DHCP is used Factors that affected performance of Networks Interface Cards (NIC) The following factors have significant impacts on the level of performance of the NIC: Operating System: Usually the OSs that have light weighted device driver give better performance with regards to network cards (Wong, Yin and Lee, 2011). Bus Speed: the Bus Speed is dependent on the ISA slot or the PCI slot. Computers having PCI slots perform better because of better speed compared to the others. Memory space: naturally NIC performs better in the environments where there is the presence of larger memory space in the computers CPU (Yu and Lin, 2012). Access technique: computers use different methods to access memory. For example DMA or Dynamic Memory Allocation gives better results with regards to NIC performance than that of Input/output methods. Discussion of how drivers are implemented for various network components The steps of removing the NIC driver: On the server of CCBoot, the super client is enabled for a PC (PC101) Diskless boot PC101 The CCBootClient program is run In the CCBOOTClient dialog box, the button NICPnP is clicked In the pop up CCBOOTPnP dialog box, the Install Known NIC button is clicked. In the pop up NIC Drivers dialog box, the NVIDIAnForce Networking Controller check box is unchecked and then OK button is clicked Then PC101 is shutdown At last, on the CCBoot server, the supper client is diabled The steps to update the NIC driver: Click start from the taskbar and in the popup menu click Control Panel Double click System from the listed menu items In the dialog box, click on the tab labeled Hardware in the page that appears click Device Manager In the device manager dialog box that appears install the drivers Click on the driver mane to update The driver is automatically updated Determination a cabling and hardware connection configuration for a given site Fiber-optic cable: Fiber optic cables are typically the most popular and widely used mode of data transmission of modern days. The optical fiber can carry light. Fiber optics is known mostly for long distance high speed data communication (Xie and Zhao, 2014). Modern day fiber optics can have the capacity to carry and transmit data over 50 kilometers or more having bandwidth of about 1 terabyte per second. One of the prominent examples of optical fiber usage is the Internet. Using fiber optic cables data is digitally transmitted over network instead of analogically (Dalle, 2015). BNC connector: The hardware connection configuration used in the given scenario is BNC connector. This type of connector is used in network of Token ring. The user can connect to the computer as well as relay traffic from one computer to other computer and connect to a FTP network to hide the IP address (Esbensen, Geladi and Larsen, 2014). Task 2 Laboratory 2: Peer to Peer Networks 2. Discussion of the various distributed computing approaches of client-server networks and peer-to-peer approaches In respect of P2P (peer-to-peer) networks, distributed computing means the services of network will be distributed among the nodes in the network. In this, every node will have play an equal role as there will be no elements in the centre. One such architecture of P2P can be given as early design of internet which is ARPANET. However, according to client-server networks distributed computing have an important role to play as it will need a centralized system. This model enables a system to expand its abilities by utilizing the resources being shared by other hosts. Distributed computing can allocate huge amount of resources to fewer computers. The more load is reduced from the clients the more it will be simpler for clients to operate in this model. 3. Explanation of the functions of client-server computers on a network The computer server on a network shares resources with clients. An immediate request process starts with the demand for services by the clients. Whereas, the client computers do not share any resources but in turn sends request to the server host for function or service. The client and server communicate in a request-response pattern: the client sends a request and the server responds to the request. An example of such interaction can be given as the mail systems in which the client requests for a particular mail service like Gmail or Yahoo and the server responds by providing the web page of that mail service. 4. Description of the advantages of client-server approaches in centralized services The advantages should be described as follows: Security of data Data is being stored on servers which provide better security than client. Accessibility The resources or data can be accessed or changed by clients only with prior permissions of the servers. Data backup Provides with ease to update data anytime. Functionality It can provide function or services to various clients with different capabilities at the same time. Maintenance The servers can be repaired, upgraded or relocated without affecting the clients. Flexibility New technology can be easily implemented and the servers can be remotely accessed irrespective of platforms. User accounts It provides with an ease to add or remove clients without affecting the network. Performance This approach can increase performance without much hassle as the client side need not to be disturbed for any modifications. Task 3 Laboratory 3: Open System Interconnection Model 1. Presentation of OSI Layered Model The layers in OSI model is described with the help of diagrams as below (Xie and Zhao, 2014): Physical Layer One of the significant elements of the physical layer is to move information as electromagnetic flags over a transmission medium. It is in charge of developments of individual bits from one bounce (Node) to next. Both information and the signs can be either simple or advanced (Esmail and Fathallah, 2015). Transmission media work by leading vitality along a physical way which can be wired or wireless. Data Link Layer Data Link Layer is in charge of moving casings starting with one bounce Hop (Node) then onto the next. It is mindful to sort out bits into casings; to give Hop-to-Hop conveyance. It is concerned with physical tending to control the flow, control the error and access co Network Layer The Network layer is in charge of the conveyance of individual bundles from the source host to the destination host. This layer is concerned with intelligent tending to implies IP tending to and directing means the transmission of information in the system from source to destination. It is also responsible for handling of errors, controlling congestion, sequencing of packets and creating internetworks (Fathallah and Esmail, 2015). Transport Layer This layer has the responsibility of delivering message from on to other process. It also concerns recovery of error from beginning to end of transmission. It is also responsible for control of flow and transfer of complete data. Session Layer This layer is responsible for controlling dialog and synchronization. This layer deals with management and termination of connections between applications. It helps to deal and coordinate session and connection. Presentation Layer This layer helps in conversion, compression and encryption. It helps to transform data into the form that is acceptable by the application layer. It provides freedom from differences in the representation of data (Gao, An and Zhu, 2014). It helps in formatting and encryption of data to be sent over the network. Application Layer This layer provides services to the users. This layer consists of everything that is specific to applications. It supports the processes of end-users. There exist two applications Telnet and FTP that is specific only to this layer. 2. Role of data packets and Transmission of OSI model A Data packet can be defined as that unit of data built into a single package to transmit over a given path of network. The significant role played by the data packets is the broadcast of data in Internet Protocol (IP) through which the user can navigate the web or other networks (Pour Ahmadi, 2014). A Data packet is built up of various components rather than only containing raw data. The components of this are headers which contains specific types of metadata in addition to information of routing means the path in the network. As for example, an IP data packet contains headers having IPs of source and destination. It may also contain a trailer that helps to improve the transmission of data. The data packet transmission in the OSI model can be explained by taking a simple example for accessing the web page of a renowned search provider Google as below (Kuhfittig, 2013): Physical Layer The user inputs the address of Google and then this layer starts to transmit the request to next layer by any physical media wired or wireless. Data Link Layer In this layer the data means address of the web page in the form of bits is transformed into frames and adds headers to the data packet. Network Layer - In this layer, the data packet is being logically addressed means the IP of the source is embedded into the header of the data packet. Transport Layer This layer then sends the received data packet to the next layer for processing of the data. Session Layer This layer then opens up ports for transmission and synchronizes the data packet. Presentation Layer This layer then encrypts the data along with the destination IP and transmits to the next layer in the model. Application Layer This layer finally transmits the data packet containing the source IP and destination IP along with routing information to the user for getting the web page of Google in the system (Politi, Anagnostopoulos and Stavdas, 2012). 3. Role of different layers protocol OSI protocols can be defined as set of principles to facilitate the exchange of information between the different layers of the model. The role of protocols at different layers of the OSI model can be discussed as follows (Kwon, Kim and Lee, 2011): Physical Layer In this the protocols helps to deal with the hardware of the networks. Data Link Layer The protocols in this layer compiles and transforms the received data into frames. Network Layer in this device like routers and switches are used and the protocols help to transmit data between nodes thus facilitating real time processes. Transport Layer It uses the most important protocols to transmit data from source to destination node. Session Layer The protocols helps to create and terminate connection for transmission of data. Presentation Layer This layers protocol are involved in the encryption and decryption of data. Application Layer The protocols ensure interaction of the users with the applications. Some of the specific protocols and their functions can be discussed as below (Li, 2014): DSL (Digital Subscriber Line) It is a protocol of physical layer used for the purpose of understanding on how the network of telecommunications connects with each other. ARP (Address Resolution Protocol) This protocol in data link layer is used for resolution of addresses in network layer into addresses of link layer. IPv4 (Internet Protocol version 4) This protocol provides the network layer with a checksum for protection of the headers of data packets. TCP (Transmission Control Protocol) This provides the transport layer with reliability for data transmissions. PPTP (Point-to-Point Tunneling Protocol) This protocol of session layer acts as tunnel to connect user and application processes. SSL (Secure Sockets Layer) It is a protocol of presentation layer that provides the users to run services that are secure on specific applications. FTP (File Transfer Protocol) This protocol for application layer provides the user with reliability to send or retrieve all types of files (Pardeshi and Mungray, 2014). 4. Explanation of transmission between different network layers The various examples of transmission in different layers can be explained in the following manner (Mathew, 2015): Access a web page If a user wants to access a web page then a request process is initiated in the Physical Layer and data is transferred to Data Link Layer. In which hardware address encapsulation is done and transmitted to Network Layer for network encapsulation. After that Transport Layer encapsulates the destination port and Session Layer manages opening and closing of connections. The Presentation Layer performs compression and sequencing of data. And finally, the Application Layer provides user for interaction with the network. Connection to a database in remote location The user requests for a database connection and retrieval of data from the network moves via the Physical Layer with request parameters as bits of information. Then the Data Link Layer transforms the data into frames and encapsulates the hardware information of the client (Meyer et al. 2012). Next is the Network Layer, in which the network address of client is attached with the requests data and transmitted to Transport Layer. This layer invokes the information of source and destination addresses into the packet and sends to Session Layer to establish a connection with the destination host. Now the Presentation Layer compresses the retrieved data, provides it to Application Layer for user interaction with the network, and fulfils the requirements of the user of the system. 5. Explanation of the relationship of drivers to the OSI model NIC provides some of the operations to the second layer of the model of OSI. The interface of NIC is a device of physical layer and the physical address that is referred as MAC address of the drivers to control the NIC that is located at the data link layers MAC sub layer (Gao, An and Zhu, 2014). In an Ethernet, the NIC attached the same segment receives the frames to determine the MAC address. The frames that match with the local address of NIC are forwarded to the OSI model to the next layer to process by the protocol of network layer (Wong, Yin and Lee, 2011). 6. Explanation of detailed operation of different IEEE 802.N network configurations IEEE 802.2 (Logic Link Control) This can be defined as paradigm for the sub layer of the upper Data Link Layer and also called as Logic Link Control layer. Generally, it is concerned with the management of traffic over the physical network (Jaumard and Hoang, 2012). It is responsible to perform operations like error and flow control in the network. IEEE 802.3 (Ethernet) This is a standard adapted by Ethernet for operations and it is the paradigm for CSMA/CD (Carrier Sense Multiple Access with Collision Detection) which includes standards of both the MAC and Physical Layer (Wilson et al. 2014). The term CSMA/CD is that which is used by Ethernet to manage access to the medium of the network like network cable. In the event that there is no information, any node may endeavor to transmit, if the nodes realize a collision, both quit transmitting and hold up an arbitrary measure of time before retransmitting the information (Vakulya, Tuza and Simon, 2015). IEEE 802.5 (Token Ring) The token is a special frame which is intended to travel out from node to node around the ring. Every node on the system checks the token for expected information and acknowledges the information and transmits another token. If the information is not for that node it retransmits to the next node (Jesi, Montresor and Babaoglu, 2012). IEEE 802.11 (Wireless Network Standards) The various standards use different frequency for network connection and have limited speeds in rates of data transfer. The connections through Wireless LANs mainly use CSMA/CA - Carrier Sense Multiple Access/Collision Avoidance for minimization of collisions in the network thus resulting into fewer requirements for retransmission of data (Jiahu Qin and Changbin Yu, 2013). Reference of the 802 protocols to the existing OSI layers The services as well as protocols in IEEE 802 maps the lower two layers of the OSI networking reference model i.e. Data Link layer and Physical layer. IEEE 802 splits the data link layer of OSI into two sub layers that is referred to as Logical Link Control as well as Media Access Control (Takayasu, Chiesa and Minervini, 2014). Conclusion The proposal gives a clear insight to the various networking methodologies in order to choose and implement the appropriate network architecture that meets the network implementation requirements. The basic network components are discussed along with their individual functionalities. The connection materials and network components apply to the organisations networking architecture. The chosen architecture and topology for the network are explained in detail in terms of how it will be beneficial to the organizations business. The performance related issues are measured in terms of meeting the requirements and considering improvement in business. Furthermore, comparison between peer to peer and client server architecture and detail working of the various network elements are provided. Reference List Ahmad, H., Zulkifli, A., Kiat, Y. and Harun, S. (2014). Q-switched fibre laser using 21cm Bismuth-erbium doped fibre and graphene oxide as saturable absorber.Optics Communications, 310, pp.53-57. Asghar, M. and Ghanbari, M. (2012). MIKEY for keys management of H.264 scalable video coded layers.Journal of King Saud University - Computer and Information Sciences, 24(2), pp.107-116. Bajwa, I., Lee, M. and Bordbar, B. (2012). Translating natural language constraints to OCL.Journal of King Saud University - Computer and Information Sciences, 24(2), pp.117-128. Beko, M. and Dinis, R. (2014). Systematic Method for Designing Constellations for Intensity-Modulated Optical Systems.Journal of Optical Communications and Networking, 6(5), p.449. Bhaskar, D. and Mallick, B. (2015). Performance Evaluation of MAC Protocol for IEEE 802. 11, 802. 11Ext. WLAN and IEEE 802. 15. 4 WPAN using NS-2.International Journal of Computer Applications, 119(16), pp.25-30. Buerschaper, O. (2014). Twisted injectivity in projected entangled pair states and the classification of quantum phases.Annals of Physics, 351, pp.447-476. Burnstock, G. (2013). Purinergic signalling in visceral organs in health and disease: Preface.Purinergic Signalling, 10(1), pp.1-1. Cheong, Y., Chong, W., Chong, S., Lim, K. and Ahmad, H. (2014). Regenerated Type-IIa Fibre Bragg Grating from a GeB codoped fibre via thermal activation.Optics Laser Technology, 62, pp.69-72. Clear, N. (2014). The Gold Mine: A Ludic Architecture.Architectural Design, 84(4), pp.128-133. Cui, S. (2015). A Optimization Traffic Grooming Algorithm Based on Bidirectional SONET Ring Topology Network.AMM, 727-728, pp.996-999. Dalle, C. (2015). Differentiated Doping Profile for Vertical Terahertz GaN Transferred-Electron Devices.IEEE Trans. Electron Devices, 62(3), pp.802-807. Esbensen, K., Geladi, P. and Larsen, A. (2014). Myth: Light travels to and from the sample in a fibre-optic cable without problems.NIR news, 25(6), p.25. Esmail, M. and Fathallah, H. (2015). Indoor visible light communication without line of sight: investigation and performance analysis.Photonic Network Communications. Fathallah, H. and Esmail, M. (2015). Performance evaluation of special optical coding techniques appropriate for physical layer monitoring of access and metro optical networks.Photonic Network Communications. Gao, X., An, Y. and Zhu, K. (2014). 2FSK Modem Based on the Microcontroller AT89C51.Journal of Networks, 9(8). Hassan, M. (2012). An efficient method to solve least-cost minimum spanning tree (LC-MST) problem.Journal of King Saud University - Computer and Information Sciences, 24(2), pp.101-105. Huang, J. and Zhou, L. (2014). Peach gum polysaccharide polyelectrolyte: Preparation, properties and application in layer-by-layer self-assembly.Carbohydrate Polymers, 113, pp.373-379. Imran, M., Zafar, N., Alnuem, M., Aksoy, M. and Vasilakos, A. (2015). Formal verification and validation of a movement control actor relocation algorithm for safetycritical applications.Wireless Netw. Jaumard, B. and Hoang, H. (2012). Design and Dimensioning of Logical Survivable Topologies Against Multiple Failures.Journal of Optical Communications and Networking, 5(1), p.23. Jesi, G., Montresor, A. and Babaoglu, O. (2007). Proximity-Aware Superpeer Overlay Topologies.IEEE Transactions on Network and Service Management, 4(2), pp.74-83. Jiahu Qin, and Changbin Yu, (2013). Coordination of Multiagents Interacting Under Independent Position and Velocity Topologies.IEEE Trans. Neural Netw. Learning Syst., 24(10), pp.1588-1597. Katugampola, H., Halder, W., Ganatra, R., Dunkel, L., Storr, H., Guasti, L. and King, P. (2014). Expression of Sonic hedgehog signalling components in the developing human adrenal cortex.Endocrine Abstracts. KiranRana, P. and Setia, D. (2015). OFDM Synchronization Techniques Analysis for IEEE 802. 16d Review.International Journal of Computer Applications, 115(11), pp.1-4. Koodziejczyk, M. and Ogiela, M. (2012). Applying of security mechanisms to middle and high layers of OSI/ISO network model.Theoretical and Applied Informatics, 24(1). Kuhfittig, P. (2013). Neutron Star Interiors and Topology Change.Advances in Mathematical Physics, 2013, pp.1-4. Kumar, S. and Kumar, M. (2012). Application of neural network in integration of shape from shading and stereo.Journal of King Saud University - Computer and Information Sciences, 24(2), pp.129-136. Kwon, H., Kim, K. and Lee, C. (2011). The unified UE baseband modem hardware platform architecture for 3GPP specifications.Journal of Communications and Networks, 13(1), pp.70-76. Li, H. (2014). Application of Stress Absorbing Layer in Project.AMM, 587-589, pp.1095-1099. Mathew, A. (2015). A thick subcategory theorem for modules over certain ring spectra.Geom. Topol., 19(4), pp.2359-2392. Meyer, Q., Keinert, B., Suner, G. and Stamminger, M. (2012). Data-Parallel Decompression of Triangle Mesh Topology.Computer Graphics Forum, 31(8), pp.2541-2553. Pardeshi, P. and Mungray, A. (2014). Synthesis, characterization and application of novel high flux FO membrane by layer-by-layer self-assembled polyelectrolyte.Journal of Membrane Science, 453, pp.202-211. Politi, C., Anagnostopoulos, V. and Stavdas, A. (2012). PLI-Aware Routing in Regenerated Mesh Topology Optical Networks.J. Lightwave Technol., 30(12), pp.1960-1970. Pour Ahmadi, M. (2014). A Basic Method for Naming Persian Karbandis Using a Set of Numbers.Nexus Netw J, 16(2), pp.313-343. Rastgar, S. and Shahrokhian, S. (2014). Nickel hydroxide nanoparticles-reduced graphene oxide nanosheets film: Layer-by-layer electrochemical preparation, characterization and rifampicin sensory application.Talanta, 119, pp.156-163. Schwartz, N. and Stone, L. (2013). Exact epidemic analysis for the star topology.Physical Review E, 87(4). Takayasu, M., Chiesa, L. and Minervini, J. (2014). Investigation of REBCO Twisted Stacked-Tape Cable Conductor Performance.J. Phys.: Conf. Ser., 507(2), p.022040. Vakulya, G., Tuza, Z. and Simon, G. (2015). Optimal Multi-TDMA Scheduling in Ring Topology Networks.Mathematical Problems in Engineering, 2015, pp.1-14. Wilson, T., Garner, L., Metcalfe, C., King, E., Margraf, S. and Brown, M. (2014). Fine Specificity and Molecular Competition in SLAM Family Receptor Signalling.PLoS ONE, 9(3), p.e92184. Wong, P., Yin, D. and Lee, T. (2011). Performance analysis of Markov modulated 1-persistent CSMA/CA protocols with exponential backoff scheduling.Wireless Netw, 17(8), pp.1763-1774. Xie, H. and Zhao, J. (2014). A lightweight identity authentication method by exploiting network covert channel.Peer-to-Peer Networking and Applications. Xie, H. and Zhao, J. (2014). A lightweight identity authentication method by exploiting network covert channel.Peer-to-Peer Networking and Applications. Yu, C. and Lin, J. (2012). A Mesh Topology Approach for Bluetooth Scatternet Formation.AMM, 182-183, pp.1105-1109. Yu, C. and Lin, J. (2012). Enhanced Bluetree: a mesh topology approach forming Bluetooth scatternet.IET Wireless Sensor Systems, 2(4), pp.409-415.
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