In queueing theory, a discipline within the mathematical theory of probability, the flow-equivalent server method (also known as flow-equivalent aggregation technique, [1] Norton's theorem for queueing networks or the Chandy–Herzog–Woo method [2]) is a divide-and-conquer method to solve product form queueing networks inspired by Norton's theorem for electrical circuits. [3] The network is successively split into two, one portion is reconfigured to a closed network and evaluated.
Marie's algorithm is a similar method where analysis of the sub-network are performed with state-dependent Poisson process arrivals. [4] [5]
In queueing theory, a discipline within the mathematical theory of probability, the flow-equivalent server method (also known as flow-equivalent aggregation technique, [1] Norton's theorem for queueing networks or the Chandy–Herzog–Woo method [2]) is a divide-and-conquer method to solve product form queueing networks inspired by Norton's theorem for electrical circuits. [3] The network is successively split into two, one portion is reconfigured to a closed network and evaluated.
Marie's algorithm is a similar method where analysis of the sub-network are performed with state-dependent Poisson process arrivals. [4] [5]