Neural-network-based call admission control in ATM networks with heterogeneous arrivals

Call admission control (CAC) has been accepted as a potential solution for supporting diverse, heterogeneous traffic sources demanding different quality of services in asynchronous transfer mode (ATM) networks. Besides, CAC is required to consume a minimum of time and space to make call acceptance d...

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Bibliographic Details
Main Authors: Hah, J.M., Tien, P.L., Yuang, M.C.
Format: Conference Proceeding
Language:English
Subjects:
Analytical models
Asynchronous transfer mode
Call admission control
Communication system traffic control
Delay estimation
Quality of service
Queueing analysis
Telecommunication traffic
Traffic control
Training data
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Summary:Call admission control (CAC) has been accepted as a potential solution for supporting diverse, heterogeneous traffic sources demanding different quality of services in asynchronous transfer mode (ATM) networks. Besides, CAC is required to consume a minimum of time and space to make call acceptance decisions. We present an efficient neural-network-based CAC (NNCAC) mechanism for ATM networks with heterogeneous arrivals. All heterogeneous traffic calls are initially categorized into various classes. Based on the number of calls in each class, the NNCAC efficiently and accurately estimates the cell delay and cell loss ratio of each class in real time by means of a pre-trained neural network. According to our decent study which exhibits the superiority of the employment of analysis-based training data over simulation-based data, we particularly construct the training data from heterogeneous-arrival dual-class queueing model M/sup [N1]/+I/sup [N2]//D/1/K, where M and I represent the Bernoulli process and interrupted Bernoulli process, and N/sub 1/ and N/sub 2/ represent the corresponding numbers of calls, respectively. Analytic results of the queueing model are confirmed by simulation results. Finally, we demonstrate the profound agreement of our neural-network-based estimated results with analytic results, justifying the viability of our NNCAC mechanism.
ISSN:0742-1303
DOI:10.1109/LCN.1996.558154