scholarly journals Admission Control and Bandwidth Allocation for Class A Traffic in RPR Networks

2021 ◽  
Author(s):  
Zhenning Xu
Keyword(s):  
Admission Control ◽  
Bandwidth Allocation ◽  
Control Mechanism ◽  
Available Bandwidth ◽  
Delay Performance ◽  
Low Delay ◽  
Admission Decision ◽  
Simulation Results ◽  
Allocation Algorithms

In this thesis, we study the admission control and bandwidth allocation methods for classA traffic in RPR networks. First, we investigate the performance of classA traffic under the current RPR protocol. The simulation results show that RPR networks can support low-delay classA traffic even if the networks are congested with classB and classC traffic. The low-delay performance, however, is subject to the condition that the load of classA traffic must be properly controlled. Consequently, an admission control mechanism must be used for classA traffic. In this thesis, several admission control algorithms are studied. They are the Simple Sum algorithm, the Measured Sum algorithm, and the Equivalent Bandwidth algorithm. The simulation results show that the Equivalent Bandwidth algorithm is the most suitable to use as the admission control mechanism for classA traffic. The admission control mechanism makes admission decision based on the available bandwidth allocated to the classA traffic. The existing RPR standard assumes the bandwidth allocated for classA traffic at each node is fixed. The fixed bandwidth allocation introduces inflexibility and inefficient use of bandwidth for classA traffic. In this thesis, three bandwidth allocation algorithms are proposed to dynamically allocate bandwidth for classA traffic. These algorithms have different levels of complexity and can be applied to different traffic environments. Simulation results show that the proposed algorithms improve the bandwidth efficiency of the RPR networks. The proposed algorithms are also readily integrated with the existing Internet Quality of Services (QoS) paradigms such as Diffserv and RSVP services.

scholarly journals Admission Control and Bandwidth Allocation for Class A Traffic in RPR Networks

2021 ◽  
Author(s):  
Zhenning Xu
Keyword(s):  
Admission Control ◽  
Bandwidth Allocation ◽  
Control Mechanism ◽  
Available Bandwidth ◽  
Delay Performance ◽  
Low Delay ◽  
Admission Decision ◽  
Simulation Results ◽  
Allocation Algorithms

In this thesis, we study the admission control and bandwidth allocation methods for classA traffic in RPR networks. First, we investigate the performance of classA traffic under the current RPR protocol. The simulation results show that RPR networks can support low-delay classA traffic even if the networks are congested with classB and classC traffic. The low-delay performance, however, is subject to the condition that the load of classA traffic must be properly controlled. Consequently, an admission control mechanism must be used for classA traffic. In this thesis, several admission control algorithms are studied. They are the Simple Sum algorithm, the Measured Sum algorithm, and the Equivalent Bandwidth algorithm. The simulation results show that the Equivalent Bandwidth algorithm is the most suitable to use as the admission control mechanism for classA traffic. The admission control mechanism makes admission decision based on the available bandwidth allocated to the classA traffic. The existing RPR standard assumes the bandwidth allocated for classA traffic at each node is fixed. The fixed bandwidth allocation introduces inflexibility and inefficient use of bandwidth for classA traffic. In this thesis, three bandwidth allocation algorithms are proposed to dynamically allocate bandwidth for classA traffic. These algorithms have different levels of complexity and can be applied to different traffic environments. Simulation results show that the proposed algorithms improve the bandwidth efficiency of the RPR networks. The proposed algorithms are also readily integrated with the existing Internet Quality of Services (QoS) paradigms such as Diffserv and RSVP services.

Hierarchical QoS Admission Control Mechanism for IEEE 802.16j Mobile Multi-Hop Relay WiMAX Network

2014 ◽  
pp. 205-218
Author(s):  
Rohaiza Yusoff ◽  
Mohd Dani Baba ◽  
Muhammad Ibrahim
Keyword(s):  
Real Time ◽  
Admission Control ◽  
Performance Metrics ◽  
Control Mechanism ◽  
Bandwidth Utilization ◽  
Control Approach ◽  
Ieee 802.16J ◽  
Set Up ◽  
Wimax Network

This chapter presents some performance issues in Worldwide Interoperability for Microwave Access (WiMAX) network and focus on the capability of non-transparent relay in Mobile Multi-Hop Relay (MMR) WiMAX Network. In this work, an admission control mechanism with hierarchy Quality of Service (QoS) is developed for the relay architecture. An open source-based simulator is used to evaluate the three types of QoS classes, which are Unsolicited Grant Access (UGS), Real Time Polling Service (rtPS), and Non-Real Time Polling Service (nrtPS). Two scenarios of non-transparent relay topologies are set up for different numbers of subscribers with different types of QoS application classes. Three performance metrics, which are bandwidth utilization, number of slots used, and number of admitted service flow, are observed and plotted in graph. The results show the hierarchy-based QoS admission control mechanism can enhance the throughput of provided services by 35% compared to the conventional method without the admission control approach.

scholarly journals Fuzzy Logic Partition-Based Call Admission Control for Mobile WiMAX

2011 ◽  
Vol 2011 ◽  
pp. 1-9 ◽  
Author(s):  
D. S. Shu'aibu ◽  
S. K. Syed Yusof ◽  
N. Fisal ◽  
S. H. S. Ariffin ◽  
R. A. Rashid ◽  
...  
Keyword(s):  
Fuzzy Logic ◽  
Quality Of Service ◽  
Wireless Network ◽  
Admission Control ◽  
Bandwidth Allocation ◽  
Call Admission Control ◽  
Mobile Wimax ◽  
Bit Rate ◽  
Call Admission

The unpredictable nature of the wireless network and exponential growth in traffics with different quality of service requirements has led hardware complexity to escalate. In order to effectively control and manage the network traffics, there is a need for intelligent call admission control (CAC) in admitting traffics into the wireless network that provides necessary quality of service. In this paper, we propose a fuzzy logic partition-based call admission control (FZ CAC). The scheme primarily partitions the total link bandwidth into three which corresponds to constant bit rate (CBR), variable bit rate (VBR) and handover (HO) services. The fuzzy logic admission control scheme was implemented in the HO portion to intelligently keep dropping probability as low as possible based on the available bandwidth. Simulation results showed that the proposed approach outperformed both partition-based CAC (PB CAC) and conventional bandwidth allocation CAC (CB CAC).

Adaptive channel-superframe allocation (ACSA) for 20 GHz wireless networks

2021 ◽  
Author(s):  
Majid Veyseh
Keyword(s):  
Real Time ◽  
Bandwidth Allocation ◽  
Performance Metrics ◽  
Channel Allocation ◽  
Center Frequency ◽  
60 Ghz ◽  
Allocation Algorithm ◽  
Ieee 802.15.3 ◽  
Simulation Results

Millimeter-wave (MMW) systems are high frequency wireless systems with a center frequency of around 60 GHz. This thesis deals with adaptive channel-superframe allocation (ACSA) for such system. An adaptive bandwidth or channel allocation algorithm is utilized in the piconet controller (PNC) and a new superframe structure is designed in order to distribute bandwidth among real-time (RT) and non-real-time (NRT) flows. We propose to serve RT and NRT flows separately in different channels instead of serving them in different times. We also propose to 'change the sliced superframe of IEEE 802.15.3 to an adaptive unsliced superframe in order to decrease the TCP round-trip time. We simulated a MMW system with appropriate parameters using 802.15.3 MAC as well as ACSA MAC. We meaSured three performance metrics (throughput, delay and fairness), which we aimed to improve in our superframe design. The simulation results show that the adaptive superframe structure . could provide' throughput improvements not only for NRT flows, but also for RT flows. The control algorithm in PNC could manage the bandwidth allocation in superframe and improve the throughput of RT flows. The channel access delay is improved by providing an unsliced superframe, which eliminated an imposed delay on TCP connections. Finally, the better distribution of bandwidth in ACSA MAC improves the fairness of the system. As a brief, the simulation results support the analysis of the proposed adaptive channelsuperframe allocation algorithm, which could generally improve the quality of service for MMW systems.

Interference Aware Resource Allocation in Relay Enhanced Broadband Wireless Access Networks

2013 ◽  
pp. 18-46
Author(s):  
Preetha Thulasiraman
Keyword(s):  
Resource Allocation ◽  
Bandwidth Allocation ◽  
Network Performance ◽  
Wireless Access Networks ◽  
Routing Metric ◽  
Broadband Wireless ◽  
Fair Bandwidth Allocation ◽  
Future Challenges ◽  
Allocation Algorithms

First, a novel interference aware routing metric for multipath routing considering both interflow and intraflow interference will be discussed. Second, in order to ensure quality of service (QoS), an interference aware max-min fair bandwidth allocation algorithm is addressed using lexicographic ordering and optimization. A comparison among various interference based routing metrics and interference aware bandwidth allocation algorithms established in the literature is shown through simulation results derived from NS-2 and CPLEX. It is shown that the proposed interference aware resource allocation framework improves network performance in terms of delay, packet loss ratio, and bandwidth usage. Lastly, future challenges and emerging research topics and opportunities are outlined.

scholarly journals QoS ANALYSIS FOR SCHEDULING SCHEMES IN WIRELESS NETWORKS

2012 ◽  
pp. 47-53
Author(s):  
N. Mahendran
Keyword(s):  
Wireless Networks ◽  
Quality Of Service ◽  
Bandwidth Allocation ◽  
Scheduling Algorithms ◽  
Priority Queue ◽  
Available Bandwidth ◽  
Periodic Fluctuation ◽  
Wireless Environment ◽  
Bandwidth Allocation Algorithm

In wireless environment, the periodic moments of wireless networks may cause the fluctuation of available bandwidth by varying with time and location. The periodic fluctuation disturbs the resource distribution and Quality of Service (QoS). Qos design is the fundamental functionality of the networking router to enable differentiated delivery and to guarantee the delivery quality for different service traffic classes. By differentiating service classes with appropriate scheduling algorithms, improve the performance of QoS. In this paper, we investigate the compensation issues of fair and priority scheduling algorithms and propose a efficient adaptive bandwidth allocation algorithm for wireless networks, called Adaptive Rotating priority Queue (ARPQ). We evaluate the performance and effectiveness of each scheduling algorithms to meeting the desired QoS requirements.

scholarly journals Adaptive channel-superframe allocation (ACSA) for 20 GHz wireless networks

2021 ◽  
Author(s):  
Majid Veyseh
Keyword(s):  
Real Time ◽  
Bandwidth Allocation ◽  
Performance Metrics ◽  
Channel Allocation ◽  
Center Frequency ◽  
60 Ghz ◽  
Allocation Algorithm ◽  
Ieee 802.15.3 ◽  
Simulation Results

Millimeter-wave (MMW) systems are high frequency wireless systems with a center frequency of around 60 GHz. This thesis deals with adaptive channel-superframe allocation (ACSA) for such system. An adaptive bandwidth or channel allocation algorithm is utilized in the piconet controller (PNC) and a new superframe structure is designed in order to distribute bandwidth among real-time (RT) and non-real-time (NRT) flows. We propose to serve RT and NRT flows separately in different channels instead of serving them in different times. We also propose to 'change the sliced superframe of IEEE 802.15.3 to an adaptive unsliced superframe in order to decrease the TCP round-trip time. We simulated a MMW system with appropriate parameters using 802.15.3 MAC as well as ACSA MAC. We meaSured three performance metrics (throughput, delay and fairness), which we aimed to improve in our superframe design. The simulation results show that the adaptive superframe structure . could provide' throughput improvements not only for NRT flows, but also for RT flows. The control algorithm in PNC could manage the bandwidth allocation in superframe and improve the throughput of RT flows. The channel access delay is improved by providing an unsliced superframe, which eliminated an imposed delay on TCP connections. Finally, the better distribution of bandwidth in ACSA MAC improves the fairness of the system. As a brief, the simulation results support the analysis of the proposed adaptive channelsuperframe allocation algorithm, which could generally improve the quality of service for MMW systems.

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