Computational analysis of a Markovian queueing system with geometric mean-reverting arrival process

• A new traffic source is proposed to accommodate continuously changing intensity.
• This model is parsimonious with two key parameters having clear physical meanings.
• A conjecture relating continuous and discrete systems is established and validated.
• Matrix geometric method and extrapolation are jointly applied for queueing analysis.
• The effects of the two key traffic parameters on queueing systems are investigated.

In the queueing literature, an arrival process with random arrival rate is usually modeled by a Markov-modulated Poisson process (MMPP). Such a process has discrete states in its intensity and is able to capture the abrupt changes among different regimes of the traffic source. However, it may not be suitable for modeling traffic sources with smoothly (or continuously) changing intensity. Moreover, it is less parsimonious in that many parameters are involved but some are lack of interpretation. To cope with these issues, this paper proposes to model traffic intensity by a geometric mean-reverting (GMR) diffusion process and provides an analysis for the Markovian queueing system fed by this source. In our treatment, the discrete counterpart of the GMR arrival process is used as an approximation such that the matrix geometric method is applicable. A conjecture on the error of this approximation is developed out of a recent theoretical result, and is subsequently validated in our numerical analysis. This enables us to calculate the performance measures with high efficiency and precision. With these numerical techniques, the effects from the GMR parameters on the queueing performance are studied and shown to have significant influences.