2015
DOI: 10.1109/lcomm.2014.2377236
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Analysis of Finite Buffer Queue: Maximum Entropy Probability Distribution With Shifted Fractional Geometric and Arithmetic Means

Abstract: A theoretical method based on maximum Shannon entropy framework (MSEF) in the presence of the geometric/ or shifted fractional geometric mean of the queue size is applied to study the finite buffer system. Analytical expression of the loss probability for large buffer size is found to depict power law behavior. The maximum entropy framework is extended to incorporate additional shifted fractional arithmetic mean constraint to yield the expression of loss probability which is similar to the one derived by Kim a… Show more

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Cited by 16 publications
(8 citation statements)
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“…Some further exemplary studies and applications of the maximization of E Sh (Q) -aside from the vast physics literature -appear e.g. in De Santis et al [106] for cryptanalytic guessing problems for breaking ciphertexts with probabilistic brute-force attacks, Johansson & Sternad [173] for tackling certain resource allocation problems under uncertainty, Marano & Franceschetti [246] for ray propagation in percolating lattices, Miao et al [260] for unsupervised mixed-pixel decomposition in image processing, Rodrigues et al [310] for modelling biological species geographic distribution, Xiong et al [400] for capturing desirable phrasal and hierarchical segmentations within a statistical machine translation context, Chan et al [76] for alignment-free DNA sequence comparison, Mann & Garnett [244] for capturing some collective behaviours of intelligent agents in social interactions, Singh et al [336] for the study of finite buffer queueing systems, Baddeley [27] for geoscientifical prediction of the occurrence of mineral deposits on regional scales, Einicke et al [118] for feature selection within change classification during running, and Han et al [152] for substructure imaging of blood cells by means of maximum entropy tomography (MET). 72)) with y ∈ R: the entropy…”
Section: Let Us Give Another Example Namelymentioning
confidence: 99%
“…Some further exemplary studies and applications of the maximization of E Sh (Q) -aside from the vast physics literature -appear e.g. in De Santis et al [106] for cryptanalytic guessing problems for breaking ciphertexts with probabilistic brute-force attacks, Johansson & Sternad [173] for tackling certain resource allocation problems under uncertainty, Marano & Franceschetti [246] for ray propagation in percolating lattices, Miao et al [260] for unsupervised mixed-pixel decomposition in image processing, Rodrigues et al [310] for modelling biological species geographic distribution, Xiong et al [400] for capturing desirable phrasal and hierarchical segmentations within a statistical machine translation context, Chan et al [76] for alignment-free DNA sequence comparison, Mann & Garnett [244] for capturing some collective behaviours of intelligent agents in social interactions, Singh et al [336] for the study of finite buffer queueing systems, Baddeley [27] for geoscientifical prediction of the occurrence of mineral deposits on regional scales, Einicke et al [118] for feature selection within change classification during running, and Han et al [152] for substructure imaging of blood cells by means of maximum entropy tomography (MET). 72)) with y ∈ R: the entropy…”
Section: Let Us Give Another Example Namelymentioning
confidence: 99%
“…Since the q-Gaussian effectively models power-law behavior with a one-parameter q, its utility is widespread in various areas, including new random number generators proposed by Thistleton, Marsh, Nelson, and Tsallis [14] and by Umeno and Sato [15]. In addition to such an important application in communication systems, queuing theory has recently incorporated the q-Gaussian, reflecting the heavy-tailed traffic characteristics observed in broadband networks [16][17][18][19]. For instance, Karmeshu and Sharma [16] introduced Tsallis entropy maximization, and, there, the q-Gaussian emerges as the queue length distributions, which suggests that Jaynes' maximum entropy principle [20][21][22] can be generalized to a framework of Tsallis entropy.…”
Section: P Imentioning
confidence: 99%
“…since the first term on the right-hand side ≤ 0 as p(x) S q,opt ≤ 1, the second term ≤ 0 from the definition of S q,opt and the fact that 0 < q < 1, and the third term ≤ 0 because of the definition ofS q,opt . Since the equality in (19) holds only if p = p opt , this implies that p opt in (17) is a unique optimal solution to T2.…”
Section: Theorem 2 (Tsallis Entropy Maximization Formentioning
confidence: 99%
“…Zhao et al [10] investigated the empirical entropy method for right censored data, which gives better coverage probability than that of the empirical likelihood method for contaminated and censored lifetime data. Singh et al [11] used a theoretical method based on maximum Shannon entropy framework to study the finite buffer system, and the advantage of the method is that it has 2 Discrete Dynamics in Nature and Society enabled one to derive the analytical closed form generalized expression of the probability distribution of queue size in finite buffer system.…”
Section: Introductionmentioning
confidence: 99%