Abstract

Acyclic phase-type distributions form a versatile model, serving as approximations to many probability distributions in various circumstances. They exhibit special properties and characteristics that usually make their applications attractive. Compared to acyclic continuous phase-type (ACPH) distributions, acyclic discrete phase-type (ADPH) distributions and their subclasses (ADPH family) have received less attention in the literature. In this paper, we present the definition, properties, characteristics and PH representations of ADPH distributions and their subclasses with finite state space. Based on the definitions of geometric and shifted geometric distributions, we propose a distinct classification for the ADPH subclasses analogous to ACPH family. We develop the PH representation for each ADPH subclass and prove them through their closure properties. The advantage of our proposed classifications is in applying precise representations of each subclass and preventing miscalculation of the probability mass function, by computing the ADPH family based on geometric and shifted geometric distributions.

Highlights

  • Phase-type (PH) distributions, introduced by Neuts (1975, 1981), form a very general class of distributions that have been successfully applied in a wide variety of stochastic disciplines for the last few decades

  • The complexity of overall system model can be controlled by Acyclic subsets of PH (APH) minimal representation (Cumani 1982)

  • The first exploration of acyclic discrete phase-type (ADPH) distributions is started by Bobbio et al (2003), and they show that similar to the continuous case (Cumani 1982), the ADPH class admits a unique minimal representation, called canonical form

Read more

Summary

Introduction

Phase-type (PH) distributions, introduced by Neuts (1975, 1981), form a very general class of distributions that have been successfully applied in a wide variety of stochastic disciplines for the last few decades. The first exploration of acyclic discrete phase-type (ADPH) distributions is started by Bobbio et al (2003), and they show that similar to the continuous case (Cumani 1982), the ADPH class admits a unique minimal representation, called canonical form. The primary attempt to define the subclass of ADPH is given by Bobbio et al (2003) They propose three canonical forms to introduce the subclasses of ADPH and present the ML estimation algorithm for one of them.

Fitting algorithm
Definition and notation
Closure properties
Subclasses of ADPH distributions based on geometric distribution
The mean and variance of geometric distribution are
Coxian distribution
The kth factorial moment can be obtained as
Derivation of SG representation
DPH and diagrammatic representation of shifted negative
Derivation of SNB representation
Due to the a
The mean and variance of shifted negative binomial distribution are
GNB n GNB
The probability mass function
Conclusions and suggestions for future research

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.