INTRODUCTION
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| WiMAX stands for Worldwide Interoperability for Microwave Access. WiMAX technology provides wireless broadband service for fixed and/or mobile users, and became a reality in 2006 when Korea Telecom started the deployment of a 2.3 GHz version of mobile WiMAX service called WiBRO The first version of the IEEE Standard 802.16-2001 [1] was completed in October 2001 and published on 8 April 2002 which defined the Wireless MAN™ air interface specification for wireless metropolitan area networks (MANs). The intention behind the first release of the standard was to define a technology for broadband wireless access (BWA) for fixed users, as an alternative to cabled access networks, such as a digital subscriber line (DSL) links. |
| Most researchers are familiar with the technical features of Wimax technology but the evolution that WiMAX went through, in terms of standardization and certification, is missing and unknown to most people. Knowledge of this historical process would however aid to understand how WiMAX has become the widespread technology that it is today. Therefore, Daan Pareit, Bart Lannoo [4] presents a survey on all relevant activities that took place within three important organizations: the 802.16 Working Group of the IEEE (Institute of Electrical and Electronics Engineers) for technology development and standardization, the WiMAX Forum for product certification and the ITU (International Telecommunication Union) for international recognition. |
| In addition to this standard, some methodologies and paths for controlling and evaluating of IEEE802.16 standard are given by Morteza Nabipoor [5]. Their main focus is on classifying and evaluating some basic subjects and topics in IEEE802.16 , based on WiMAX technology. A. Bacioccola, C. Cicconetti [1], first presented a historical overview of the IEEE 802.16 standard from the first version released in 2001 to the current version. Then, they have provided a detailed technical analysis of the PHY, MAC layer, and other relevant aspects of the new standard, including a detailed description of its relay architecture and support for self organizing networks and Femto cells. The IEEE 802.16 is a standard for broadband wireless communication in Metropolitan Area Networks (MAN). To meet the QoS requirements of multimedia applications, the IEEE 802.16 standard provides four different scheduling services: Unsolicited Grant Service (UGS), real-time Polling Service (rtPS), non-real-time Polling Service (nrtPS), and Best Effort (BE). Verification of effectiveness of these four different scheduling services wad done by Claudio Cicconetti, Alessandro Erta et al. [3] in managing traffic generated by data and multimedia sources. Performance is assessed for an IEEE 802.16 wireless system working in Point-to-Multipoint (PMP) mode, with Frequency Division Duplex (FDD), and with full-duplex Subscriber Stations (SSs). To ensure meeting the QoS requirements, the 802.16 base station must run some algorithm to allocate slots between connections. A simple and an efficient solution that is capable of allocating slots based on the QoS requirements, bandwidth request sizes, and the 802.16 network parameters is proposed by Alexander Sayenko , Olli Alanen [2]. To test the proposed solution, 802.16 MAC and PHY layers are implemented in the NS-2 simulator. According to the simulation results, the proposed scheduling solution ensures the QoS requirements of all 802.16 service classes. |
| Objectives |
| 1.Study about the working of mesh networks to identify the current trends in the deployment and designing of the mesh networks. |
| 2.To study various routing protocols, such that at the access point end and node end used by the mesh networks. |
| 3.Designing of various 802.16 mesh networks by using various configuration parameters in OPNET simulator. |
| 4.To choose various performance evaluation metrics to gather the results about the performance of the networks. |
NETWORK DESIGN AND IMPLEMENTATION
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WiMax Network and Configuration Parameters
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| To meet the defined objectives, various networks are designed as shown in figure 4.1. Each network consists of 15 hexagonal shape cells. In each cell, there are 20 WiMAX based mobile nodes using OFDMA at physical layer. To make the inter cell communication possible, each cell consist of an access point and all the access the points are connected through a backbone network by using fiber optics based point-to-point links. To generate the data in the network and to evaluate the quality of services of the network, three different client-server architecture based applications, such as FTP, Email and HTTP are configured by using application definition utility and profiles of all the defined applications are defined by using profile definition utility. |
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| Figure 1. Sample network scenario |
| To manage data flow in the network, weighted fair queue (WFQ) mechanism has been used and to control the occurrence of congestion in the queues, Random Early Detection (RED) algorithm has used configured by using optimized parameters (table 4.8). |
| For working of any network, routing protocols are also required. In the given networks, an ad hoc network routing protocol, AODV has used at node level with optimized configuration of parameters (table 4.2) and at access point level, Border Gateway Protocol (BGP) has used with default values. |
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| Table 1: Configuration Parameters of |
WiMAX LAYER
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| In this table Maximum Transmission Power refers to the total transmission power that this transmission can output on the entire channel bandwidth. The Ranging Power Setup attribute sets the power setup used by MS in initial ranging before a response is heard back from BS. The Contention Ranging Retries sends the requests. The Multiple Path Channel mode is defined on the SS and it applies to the channel between this SS’s transmitter and BS receiver. The Timer attribute is used to group linear settings that are relevant to the operation of MS. |
Results and Analysis
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| Various performance evaluation metrics have used to measure the quality of services of wimax nodes under different types of client-server architecture based applications. All the results of various metrics in graphical and tabular form are presented in this . In the last conclusion has drawn and future scope has proposed. |
Performance Evaluation Metrics
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| All the evaluation metrics that are used to evaluate the networks are as follows: |
| Load:Represents the total load (in bits/sec) submitted to WiMAX layers by all higher layers in all WiMAX nodes of the network. |
| Throughput:This statistic represents the average number of bits successfully received or transmitted by the receiver or transmitter channel per unit time, in bits per second. |
| Queuing Delay:This statistic represents instantaneous measurements of packet waiting times in the transmitter channel's queue. Measurements are taken from the time a packet enters the transmitter channel queue to the time the last bit of the packet is transmitted. |
| Delay:Represents the total load (in bits/sec) submitted to WiMAX layers by all higher layers in all WiMAX nodes of the network |
| Results and discussions :After the intensive simulation |
| all the results that are generated are given below. |
Load
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| Figure 5.1 Load (bits/sec) |
| WiMAX has shown maximum, load for http application because of the large size of the objects configured for the web pages and in each web pages, It has seen that the load is minimum for ftp protocol because ftp uses two different port to send data such that for uploading, ftp uses port number 20 and for download the files, it uses port number 21. Due to the involvement of two different ports, there are always high chances to find the channel busy and nodes have to wait to place the data over the carrier than other applications. But due to the high bandwidth, wimax shows its good sustainability to |
Delay
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| Figure 5.2 has shown delay for all kind of data traffic flowing in the configured networks. WiMAX has shown almost same delay for all type of data packets. But it has seen that WiMAX has shown less delay for http based data traffic and shown maximum delay for ftp based data traffic because of the busy carrier and nodes have to wait to place the data over the channels. Also ftp protocol has also more prone to data drop than the other applications such that email and http. |
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| Figure 5.2 Delays (sec) |
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| Figure 5.4 Throughput (bits/sec) |
| From the literature survey, it has seen that throughput always considered as a main factor to measure the quality of services of a network. Throughput of all wimax based networks under different type of applications are given in figure 5.4. From the graph, it has clearly shown that the rate of quality of services for http data is high in comparison to other types of data because http application posses minimum delay and maximum load than other applications such as FTP and Email. |
Conclusion
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| In the given work, various wimax based wireless networks are designed and each network consists of 15 hexagonal shaped cells with 20 wimax based node in each cell. To generate the data in the networks, three different applications, such that high load FTP, high load HTTP and heavy Email generating different types of data are configured. After the intensive simulation, the results are gathered in graphical and tabular form. From all the graphs, it has concluded that under the given conditions and given configurations, WiMAX shows high quality of service rates, when the networks are used to transfer HTTP based data and the performance of the networks degrades, when the network is used to upload or download the data i.e. if the networks use FTP based application. |
Future Scope
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| There will be always scope to improve the work that has done in this study. The results could be improved by choosing other configuration parameter and by running simulations for longer period. In this work only client-server architecture based applications are used. So it is also required to evaluate the quality of services of WiMAX based networks under peer-to-peer architecture based applications. Other performance evaluation metrics need to use to make the concluded results more justified. |
References
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- A. Bacioccola, C. Cicconetti et al. “IEEE 802.16: History, status and future trends.” In the proceeding of Computer Communication, p.p. 113-123, vol. 33, November 2009.
- Alexander Sayenko, Olli Alanen et al. “Scheduling solution for the IEEE 802.16 base station.” In the proceeding of Computer Networks, p.p. 96-115, vol. 52, October 2008
- Claudio Cicconetti, Alessandro Erta et al. “Performance Evaluation of the IEEE 802.16 MAC for QoS Support.” In IEEE Transactions on Mobile Computing, p.p. 26-38, vol. 6, no. 1, January 2007.
- Daan Pareit, Bart Lannoo et al. “The History of WiMAX: A Complete Survey of the Evolution in Certification and Standardization for IEEE 802.16 and WiMAX.” In IEEE Communications Surveys and Tutorials, p.p. 1-29, October 2011.
- Morteza Nabipoor, “Controlling and Evaluating of IEEE 802.16 WiMAX standard.” In 2nd International Conference on Software Technology and Engineering (ICSTE), p.p. 22-25, vol.
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